#include <hdf5.h>
#include <visit-hdf5.h>
#include <avtGhostData.h>
#if HDF5_VERSION_GE(1,8,1)
/**
 *
 * @file        avtVsFileFormat.cpp
 *
 * @brief       Implementation of base class for VSH5 visit plugins
 *
 * @version $Id: $
 *
 * Copyright &copy; 2007, Tech-X Corporation
 * See LICENSE file for conditions of use.
 *
 */

//Along with PARALLEL (defined by build system) enables
// For testing outside of VisIt, be sure to do #define PARALLEL
// domain decomposition code added by Gunther
//#define PARALLEL
//#define VIZSCHEMA_DECOMPOSE_DOMAINS
// std includes
#include <cstring>
#include <sstream>
#include <stdexcept>
#include <stdlib.h>
#include <string>

// VTK includes
#include <vtkPointData.h>
#include <vtkVisItUtility.h>
#include <vtkUnsignedCharArray.h>
#include <vtkIntArray.h>
#include <vtkInformation.h>
#include <vtkFloatArray.h>
#include <vtkDoubleArray.h>
#include <vtkStructuredGrid.h>
#include <vtkRectilinearGrid.h>
#include <vtkUnstructuredGrid.h>
#include <vtkCellType.h>

// VisIt includes
#include <avtDatabaseMetaData.h>
#include <avtMeshMetaData.h>
#include <avtVariableCache.h>
#include <DebugStream.h>
#include <InvalidVariableException.h>
#include <InvalidDBTypeException.h>
#include <VsPluginInfo.h>

#include <DBOptionsAttributes.h>
#include <avtLogicalSelection.h>
//#include <avtSpatialBoxSelection.h>

// definition of VISIT_VERSION
#include <visit-config.h>

#include <avtVsFileFormat.h>
#include <avtVsOptions.h>

#include "HighOrderUnstructuredData.h"

//#define PARALLEL 1
//#define VIZSCHEMA_DECOMPOSE_DOMAINS 1

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
#include <avtParallel.h>
#endif

// VizSchema includes
#include <VsUtils.h>
#include "VsVariable.h"
#include "VsMDVariable.h"
#include "VsVariableWithMesh.h"
#include "VsMesh.h"
#include "VsMDMesh.h"
#include "VsDataset.h"
#include "VsRectilinearMesh.h"
#include "VsUniformMesh.h"
#include "VsUnstructuredMesh.h"
#include "VsStructuredMesh.h"
#include "VsAttribute.h"
#include "VsLog.h"
#include "VsRegistry.h"
#include "VsReader.h"
#include "VsSchema.h"

#define __CLASS__ "avtVsFileFormat::"

#define CLASSFUNCLINE __CLASS__ << "(" <<instanceCounter << ")" << __FUNCTION__ << "  " << __LINE__ << "  "

int avtVsFileFormat::instanceCounter = 0;

// *****************************************************************************
//  Method: avtVsFileFormat::avtVsFileFormat
//
//  Purpose:
//      Reads in the image.
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
avtVsFileFormat::avtVsFileFormat(const char* filename,
                                 const DBOptionsAttributes *readOpts) :
  avtSTMDFileFormat(&filename, 1), dataFileName(filename),
  processDataSelections(false)
{
    instanceCounter++;

    VsLog::initialize(DebugStream::Stream3(),
                      DebugStream::Stream4(),
                      DebugStream::Stream5());

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    if (readOpts != NULL) {
        for (int i=0; i<readOpts->GetNumberOfOptions(); ++i) {
            if (readOpts->GetName(i) == "Process Data Selections in the Reader")
              processDataSelections =
                readOpts->GetBool("Process Data Selections in the Reader");
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "VizSchema reader will "
                      << (processDataSelections? "" : "not ")
                      << "process data selections" << std::endl;

    //reader starts off empty
    reader = NULL;

    //Initialize the registry for objects
    registry = new VsRegistry();
    curveNames.clear();

//  LoadData();

//check types
    if (isFloatType(H5T_NATIVE_FLOAT)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "float type checks out ok." << std::endl;
    } else {
        std::ostringstream msg;
        msg << CLASSFUNCLINE
            << "ERROR - H5T_NATIVE_FLOAT not recognized as a float.";
        VsLog::debugLog() << msg.str() << std::endl;
        EXCEPTION1(InvalidDBTypeException, msg.str().c_str());
    }

    //check types
    if (isDoubleType(H5T_NATIVE_DOUBLE)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "double type checks out ok." << std::endl;
    } else {
        std::ostringstream msg;
        msg << CLASSFUNCLINE
            << "ERROR - H5T_NATIVE_DOUBLE not recognized as a double.";
        VsLog::debugLog() << msg.str() << std::endl;
        EXCEPTION1(InvalidDBTypeException, msg.str().c_str());
    }

    herr_t err = H5check();

    if (err < 0) {
        std::ostringstream msg;
        msg << CLASSFUNCLINE
            << "HDF5 version mismatch.  Vs reader built with "
            << H5_VERS_INFO << ".";
        VsLog::debugLog() << msg.str() << std::endl;

        EXCEPTION1(InvalidDBTypeException, msg.str().c_str());
    }

    //NOTE: We used to initialize the VsReader object here
    //But now do it on demand in 'populateDatabaseMetaData'
    //To minimize I/O

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::~avtVsFileFormat
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

avtVsFileFormat::~avtVsFileFormat()
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    FreeUpResources();

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// ***************************************************************************
//  Method: avtVsFileFormat::CreateCacheNameIncludingSelections
//
//  Purpose:
//      The reader will return different data sets based on data
//      selections.  This method gives a description of what is returned
//      so that the resulting data can be reliably cached.
//
//  Programmer: Hank Childs
//  Creation:   December 20, 2011
//
// **************************************************************************

std::string
avtVsFileFormat::CreateCacheNameIncludingSelections(std::string s)
{
    int mins[3], maxs[3], strides[3];
    bool haveDataSelections = ProcessDataSelections(mins, maxs, strides);

    if (!haveDataSelections)
      return s;

    char str[1024];
    strcpy(str, s.c_str());
    size_t amt = strlen(str);
    for (size_t i = 0; i < selList.size(); i++)
    {
        if ((*selsApplied)[i])
        {
            std::string s = selList[i]->DescriptionString();
            snprintf(str+amt, 1024-amt, "_%s", s.c_str());
            amt += strlen(str);
        }
    }

    return std::string(str);
}

// ****************************************************************************
//  Method: avtVsFileFormat::RegisterDataSelections
//
//  Purpose:
//      The Vs format can exploit some data selections so get them.
//
//  Programmer: Allen Sanderson
//  Creation:   March 4, 2011
//
// ****************************************************************************

void
avtVsFileFormat::RegisterDataSelections(const std::vector<avtDataSelection_p> &sels,
                                        std::vector<bool> *selectionsApplied)
{
    selList = sels;
    selsApplied = selectionsApplied;
}

// ****************************************************************************
//  Method: avtVsFileFormat::ProcessDataSelections
//
//  Purpose:
//      The Vs format can exploit some data selections so process them.
//
//  Programmer: Allen Sanderson
//  Creation:   March 4, 2011
//
// ****************************************************************************

bool
avtVsFileFormat::ProcessDataSelections(int *mins, int *maxs, int *strides)
{
    bool retval = false;

    if( !processDataSelections )
      return retval;

    avtLogicalSelection composedSel;

    for (size_t i = 0; i < selList.size(); i++)
    {
        if (std::string(selList[i]->GetType()) == "Logical Data Selection")
        {
            avtLogicalSelection *sel = (avtLogicalSelection *) *(selList[i]);

            // overrwrite method-scope arrays with the new indexing
            composedSel.Compose(*sel);
            (*selsApplied)[i] = true;
            retval = true;
        }

        // Cannot handle avtSpatialBoxSelection without knowing the mesh.

//         else if (std::string(selList[i]->GetType()) == "Spatial Box Data Selection")
//         {
//             avtSpatialBoxSelection *sel =
//               (avtSpatialBoxSelection *) *(Sellist[i]);

//             double dmins[3], dmaxs[3];
//             sel->GetMins(dmins);
//             sel->GetMaxs(dmaxs);
//             avtSpatialBoxSelection::InclusionMode imode =
//                 sel->GetInclusionMode();

//             // we won't handle clipping of zones here
//             if ((imode != avtSpatialBoxSelection::Whole) &&
//                 (imode != avtSpatialBoxSelection::Partial))
//             {
//                 (*selsApplied)[i] = false;
//                 continue;
//             }

//             int imins[3], imaxs[3];
//             for (int j = 0; j < 3; j++)
//             {
//                 int imin = (int) dmins[j];
//                 if (((double) imin < dmins[j]) &&
//                     (imode == avtSpatialBoxSelection::Whole))
//                     imin++;

//                 int imax = (int) dmaxs[j];
//                 if (((double) imax < dmaxs[j]) &&
//                     (imode == avtSpatialBoxSelection::Partial))
//                     imax++;

//                 imins[j] = imin;
//                 imaxs[j] = imax;
//             }

//             avtLogicalSelection newSel;
//             newSel.SetStarts(imins);
//             newSel.SetStops(imaxs);

//             composedSel.Compose(newSel);
//             (*selsApplied)[i] = true;
//             retval = true;
//         }
        else
        {
            // indicate we won't handle this selection
            (*selsApplied)[i] = false;
        }
    }

    composedSel.GetStarts(mins);
    composedSel.GetStops(maxs);
    composedSel.GetStrides(strides);

    // If the user is a dumb ass and selects a dimension lower than
    // the actual dimension the min, max, and stride will be zero. So
    // fix it to be the full bounds and a stride of 1.
    for (int i = 0; i < 3; i++)
    {
        if( strides[i] == 0 )
        {
            mins[i] = 0;
            maxs[i] = -1;
            strides[i] = 1;
        }
    }

    return retval;
}

// *****************************************************************************
//  Method: avtVsFileFormat::GetMesh
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
//    Gunther H. Weber, Tue May 13 18:22:27 PDT 2014
//    Added missing () to PAR_Rank() function call for diagnostic output
//

vtkDataSet* avtVsFileFormat::GetMesh(int domain, const char* name)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Save the original name in a temporary variable
    // so that we can do some string manipulations on it
    std::string meshName = name;

    // Roopa: Check if this mesh name is a transformed mesh name. If
    // so, use the original mesh name to get data associated
    bool transform = false;
    std::string origMeshName = registry->getOriginalMeshName(meshName);
    if (!origMeshName.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Original mesh for this transformed mesh "
                          << meshName << " is " << origMeshName << std::endl;
        transform = true;
        meshName = origMeshName;
    }

    bool haveDataSelections;
    int mins[3], maxs[3], strides[3];

    // Adjust for the data selections which are NODAL.
    if( (haveDataSelections = ProcessDataSelections(mins, maxs, strides)) ) ///TODO: check fix for assignment
    {
        VsLog::debugLog()
          << CLASSFUNCLINE << "Have a logical nodal selection for mesh  "
          << "(" << mins[0] << "," << maxs[0] << " stride " << strides[0] << ") "
          << "(" << mins[1] << "," << maxs[1] << " stride " << strides[1] << ") "
          << "(" << mins[2] << "," << maxs[2] << " stride " << strides[2] << ") "
          << std::endl;
    }

    // The MD system works by filtering the requests directed to it
    // into the name of the appropriate subordinate mesh.  For
    // example, in facets_core-edge-explicit we have three meshes
    // joined into one: MdMesh = {coreMesh, solMesh, privMesh} So if
    // we get a request for (MdMesh, 0), we change the name to
    // coreMesh and proceed normally

    // Check for MD mesh
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Looking for MD mesh with name "
                      << meshName << std::endl;

    VsMDMesh* mdMeshMeta = registry->getMDMesh(meshName);
    VsMesh* meta = NULL;

    // Found an MD mesh with this name, try to load the mesh data from it
    if (mdMeshMeta != NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found MD mesh with that name."
                          << std::endl;
        meshName = mdMeshMeta->getNameForBlock(domain);

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Request for md mesh was filtered to regular mesh: "
                          << meshName << std::endl;
        meta = mdMeshMeta->getBlock(domain);
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "No MD mesh with that name."
                          << std::endl;
    }

    // Did we succeed in loading mesh data from MD mesh?
    if (meta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Trying to find regular mesh named: "
                          << meshName << std::endl;
        meta = registry->getMesh(meshName);
    }

    if (meta != NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found mesh named: " << meshName << std::endl;

        // Uniform Mesh
        if (meta->isUniformMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Trying to load & return uniform mesh" << std::endl;

            return getUniformMesh(static_cast<VsUniformMesh*>(meta),
                                  haveDataSelections, mins, maxs, strides);
        }

        // Rectilinear Mesh
        else if (meta->isRectilinearMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Trying to load & return rectilinear mesh."
                              << std::endl;
            return getRectilinearMesh(static_cast<VsRectilinearMesh*>(meta),
                                      haveDataSelections, mins, maxs, strides, transform);
        }

        // Structured Mesh
        else if (meta->isStructuredMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Trying to load & return structured mesh" << std::endl;
            return getStructuredMesh(static_cast<VsStructuredMesh*>(meta),
                                     haveDataSelections, mins, maxs, strides);
        }

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
        // Don't know how to decompose any other type of mesh -> load it
        // on proc 0 only
        else if (PAR_Rank() > 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "In parallel mode on processor " << PAR_Rank()
                              << " and mesh is not uniform.  "
                              << "Returning NULL, mesh will be loaded on processor 0 only."
                              << std::endl;
            return NULL;
        }
#endif

        // Unstructured Mesh
        else if (meta->isUnstructuredMesh()) {

            if(meta->isHighOrder()) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Trying to load & return high order unstructured mesh" << std::endl;
                return getHighOrderUnstructuredMesh(static_cast<VsUnstructuredMesh*>(meta),
                                                    haveDataSelections, mins, maxs, strides);
            }

            else {
              VsLog::debugLog() << CLASSFUNCLINE
                                << "Trying to load & return unstructured mesh" << std::endl;
              return getUnstructuredMesh(static_cast<VsUnstructuredMesh*>(meta),
                                         haveDataSelections, mins, maxs, strides);
            }
        }

        // At this point we don't know what kind of mesh it is.
        else {
          VsLog::debugLog() << CLASSFUNCLINE
                            << "Mesh has unknown type: " << meta->getKind()
                            << ".  Returning NULL." << std::endl;
          return NULL;
        }
    }

    // Variable with mesh
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Looking for Variable-With-Mesh named " << meshName
                      << ".\n";
    VsVariableWithMesh* vmMeta = registry->getVariableWithMesh(meshName);

    if (vmMeta != NULL)
    {
        VsLog::debugLog() << CLASSFUNCLINE

                          << "Found Variable With Mesh. Loading data and returning." << std::endl;
        return getPointMesh(vmMeta, haveDataSelections, mins, maxs, strides, transform);
    }

    // Curve
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Looking for Curve with this name." << std::endl;

    vtkDataArray* foundCurve = this->GetVar(domain, name);

    if (foundCurve != NULL)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Trying to load & return curve." << std::endl;

        foundCurve->Delete();

        return getCurve(domain, name);
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Failed to load data for name and domain number.  "
                      << "Returning NULL." << std::endl;
    return NULL;
}

// *****************************************************************************
//  Method: avtVsFileFormat::getUniformMesh
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
//    Gunther H. Weber, Tue May 13 18:23:13 PDT 2014
//    Fixed computation of grid spacing
//

vtkDataSet* avtVsFileFormat::getUniformMesh(VsUniformMesh* uniformMesh,
                                            bool haveDataSelections,
                                            int* mins, int* maxs, int* strides)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // ARS - Becasue of the way the data structures are used to hold
    // structured data in VTK and VisIt the topological dimension has
    // to equal the spatial dimension. That is ONLY the last dim(s) of
    // the nodes can be 1.
    size_t numSpatialDims = uniformMesh->getNumSpatialDims();
    size_t numTopologicalDims = uniformMesh->getNumTopologicalDims();

    // Get dims of points array
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Determining dimension of points array." << std::endl;

    std::vector<int> numNodes;
    uniformMesh->getNodeDims(numNodes);

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Getting bounds for mesh." << std::endl;

    std::vector<float> lowerBounds;
    uniformMesh->getLowerBounds(&lowerBounds);

    std::vector<float> upperBounds;
    uniformMesh->getUpperBounds(&upperBounds);

    // VisIt downcasts to float, so go to float by default now.
    hid_t meshDataType = uniformMesh->getDataType();

    // Cache the data type because it's faster
    bool isDouble = isDoubleType(meshDataType);
    bool isFloat = isFloatType(meshDataType);

    if (!isDouble && !isFloat)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Error: hdf5 mesh data type not handled: "
                          << meshDataType << "Returning NULL." << std::endl;
        return NULL;
    }

    // ARS _ CURRENTLY THE START CELL IS IGNORED AS HOW IT IS TO USED IS
    // NOT FULLY DEFINED.

    // startCell -
    // VsLog::debugLog() << CLASSFUNCLINE
    //                << "Loading optional startCells attribute." << std::endl;

    // std::vector<int> startCell;
    // herr_t err = uniformMesh->getStartCell(&startCell);
    // if (err < 0) {
    //     VsLog::warningLog() << CLASSFUNCLINE
    //                         << "Uniform mesh does not have starting cell position."
    //                         << std::endl;
    // } else {
    //     // Adjust the box by startCell
    //     VsLog::debugLog() << CLASSFUNCLINE
    //                       << "Adjusting numCells by startCells." << std::endl;
    //  // ARS - THIS MAKES NO SENSE
    //     for (size_t i = 0; i < numSpatialDims; ++i)
    //       numCells[i] -= startCell[i];
    // }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Determining size of point arrays." << std::endl;

    // Storage for meshes in VisIt, which is a vtkRectilinearGrid
    // which is spatially 3D so the points must also be 3D.
    size_t vsdim = 3;
    std::vector<int> gdims(vsdim);

    // Adjust for the data selections which are NODAL. If no selection
    // the bounds are set to 0 and max with a stride of 1.
    GetSelectionBounds( numSpatialDims, numNodes, gdims,
                        mins, maxs, strides, haveDataSelections );

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
    if( !GetParallelDecomp( numSpatialDims, gdims, mins, maxs, strides ) )
      return NULL; // No work for this processor.

    haveDataSelections = 1;
#endif

    // Storage for mesh points in VisIt are spatially 3D. So create 3
    // coordinate arrays and fill in zero for the others.
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Creating coordinate arrays." << std::endl;

    std::vector<vtkDataArray*> coords(vsdim);

    for (size_t i=0; i<numSpatialDims; ++i)
    {
        if( isDouble )
          coords[i] = vtkDoubleArray::New();
        else if( isFloat )
          coords[i] = vtkFloatArray::New();

        // Delta
        double delta = 0;
        if (gdims[i] > 1)
          delta = (upperBounds[i] - lowerBounds[i]) / (numNodes[i]-1);

        int cc = 0;
        int j = mins[i];

        while( j <= maxs[i] )
        {
            double temp = lowerBounds[i] + j*delta;
            coords[i]->InsertTuple(cc, &temp);
            ++cc;
            j += strides[i];
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Dumped " << cc << " nodes to the rectilinear grid."
                          << std::endl;
    }

    // Unused axii
    for (size_t i=numSpatialDims; i<vsdim; ++i)
    {
        coords[i] = vtkFloatArray::New();
        coords[i]->SetNumberOfTuples(1);
        coords[i]->SetComponent(0, 0, 0);
    }

    // Create vtkRectilinearGrid
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Creating rectilinear grid." << std::endl;
    vtkRectilinearGrid* rgrid = vtkRectilinearGrid::New();
    rgrid->SetDimensions(&(gdims[0]));

    // Set grid data
    rgrid->SetXCoordinates(coords[0]);
    rgrid->SetYCoordinates(coords[1]);
    rgrid->SetZCoordinates(coords[2]);

    // Cleanup local data
    for (size_t i = 0; i<vsdim; ++i)
      coords[i]->Delete();

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return rgrid;
}

// *****************************************************************************
//  Method: avtVsFileFormat::getRectilinearMesh
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

vtkDataSet*
avtVsFileFormat::getRectilinearMesh(VsRectilinearMesh* rectilinearMesh,
                                    bool haveDataSelections,
                                    int* mins, int* maxs, int* strides,
                                    bool transform)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // ARS - Becasue of the way the data structures are used to hold
    // structured data in VTK and VisIt the topological dimension has
    // to equal the spatial dimension. That is ONLY the last dim(s) of
    // the nodes can be 1.
    size_t numSpatialDims = rectilinearMesh->getNumSpatialDims();
    size_t numTopologicalDims = rectilinearMesh->getNumTopologicalDims();

    // Get dims of points array
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Determining dimension of points array." << std::endl;

    std::vector<int> numNodes;
    rectilinearMesh->getNodeDims(numNodes);

    // VisIt downcasts to float, so go to float by default now.
    hid_t meshDataType = rectilinearMesh->getDataType();

    // Cache the data type because it's faster
    bool isDouble = isDoubleType(meshDataType);
    bool isFloat = isFloatType(meshDataType);

    if (!isDouble && !isFloat)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Error: hdf5 mesh data type not handled: "
                          << meshDataType << "Returning NULL." << std::endl;
        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Determining size of point arrays." << std::endl;

    // Storage for meshes in VisIt, which is a vtkRectilinearGrid
    // which is spatially 3D so the points must also be 3D.
    size_t vsdim = 3;
    std::vector<int> gdims(vsdim);

    // Adjust for the data selections which are NODAL. If no selection
    // the bounds are set to 0 and max with a stride of 1.
    GetSelectionBounds( numSpatialDims, numNodes, gdims,
                        mins, maxs, strides, haveDataSelections );

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
    if( !GetParallelDecomp( numSpatialDims, gdims, mins, maxs, strides ) )
      return NULL; // No work for this processor.

    haveDataSelections = 1;
#endif

    std::vector<vtkDataArray*> coords(vsdim);

    for( size_t i=0; i<numSpatialDims; ++i )
    {
        void* dataPtr;
        double* dblDataPtr = NULL; //TODO: check fix for uninitialized values
        float* fltDataPtr = NULL; ///TODO: check fix for uninitialized values

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Loading data for axis " << i << std::endl;
        VsDataset* axisData = rectilinearMesh->getAxisDataset((int)i);

        if (axisData == NULL) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Axis " << i
                              << " data not found. Returning NULL." << std::endl;
            return NULL;
        }

        hid_t axisDataType = axisData->getType();

        // Read points and add in zero for any lacking dimension
        if( isDoubleType( axisDataType ) ) {
            dblDataPtr = new double[gdims[i]];
            dataPtr = dblDataPtr;
        }
        else if( isFloatType( axisDataType ) ) {
            fltDataPtr = new float[gdims[i]];
            dataPtr = fltDataPtr;
        } else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Unknown axis data type: "
                              << axisDataType << std::endl;
            return NULL;
        }

        if (!dataPtr) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Allocation failed, pointer is NULL."
                              << "Returning NULL." << std::endl;
            return NULL;
        }

        // Read in the point data. NOTE: Even when doing index selecting
        // or in parallel mode read in all of the data. As for the grid
        // there is not that much data. When building the mesh the
        // correct nodes are used.
        herr_t err = reader->getData(axisData, dataPtr);

        if (err < 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "GetDataSet returned error: " << err << "  "
                              << "Returning NULL." << std::endl;

            if( isDoubleType( axisDataType ) )
              delete [] dblDataPtr;
            else if( isFloatType( axisDataType ) )
              delete [] fltDataPtr;

            return NULL;
        }

        // Storage for mesh points in VisIt are spatially 3D. So create 3
        // coordinate arrays and fill in zero for the others.
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Creating coordinate arrays." << std::endl;

        // The mesh data type will the highest precision of all of the
        // axis data types. Declaring here allows the the mesh data type
        // to be either float or double.
        if( isDouble )
          coords[i] = vtkDoubleArray::New();
        else if( isFloat )
          coords[i] = vtkFloatArray::New();

        int cc = 0;

        if (isDouble) {

            int j = mins[i];

            while( j <= maxs[i] )
            {
                double temp;

                if( isDoubleType( axisDataType ) )
                  temp = dblDataPtr[j];
                else if( isFloatType( axisDataType ) )
                  temp = fltDataPtr[j];

                coords[i]->InsertTuple(cc, &temp);
                ++cc;
                j += strides[i];
            }

            if( isDoubleType( axisDataType ) )
              delete [] dblDataPtr;
            else if( isFloatType( axisDataType ) )
              delete [] fltDataPtr;

        } else if (isFloat) {

            int j = mins[i];

            while( j <= maxs[i] )
            {
                float temp;

                if( isDoubleType( axisDataType ) )
                  temp = dblDataPtr[j];
                else if( isFloatType( axisDataType ) )
                  temp = fltDataPtr[j];

                coords[i]->InsertTuple(cc, &temp);
                ++cc;
                j += strides[i];
            }

            if( isDoubleType( axisDataType ) )
              delete [] dblDataPtr;
            else if( isFloatType( axisDataType ) )
              delete [] fltDataPtr;
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Dumped " << cc << " nodes to the rectilinear grid."
                          << std::endl;
    }

    for (size_t i=numSpatialDims; i<vsdim; ++i) {
        if( isDouble )
          coords[i] = vtkDoubleArray::New();
        else if( isFloat )
          coords[i] = vtkFloatArray::New();

        coords[i]->SetNumberOfTuples(1);
        coords[i]->SetComponent(0, 0, 0);
    }

    // Create a Rectilinear mesh and send it if there is no
    // transformation requested
    if (!transform) {
        // Create vtkRectilinearGrid
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Creating rectilinear grid." << std::endl;
        vtkRectilinearGrid* rgrid = vtkRectilinearGrid::New();
        rgrid->SetDimensions(&(gdims[0]));

        // Set grid data
        rgrid->SetXCoordinates(coords[0]);
        rgrid->SetYCoordinates(coords[1]);
        rgrid->SetZCoordinates(coords[2]);

        // Cleanup local data
        for (size_t i = 0; i < vsdim; ++i) {
            coords[i]->Delete();
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Returning data." << std::endl;
        return rgrid;
    } else {
        // Roopa: Transformation to cylindrical co-ords if transform is
        // true. Calculate the points and return a Structured mesh instead
        // of a Rectilinear mesh
        //
        float /*temp,*/ tempk, tempj, tempi;
        vtkPoints* vpoints = vtkPoints::New();
        if (isDouble) {
            vpoints->SetDataTypeToDouble();
        }
        else if (isFloat) {
            vpoints->SetDataTypeToFloat();
        }
        vpoints->SetNumberOfPoints((maxs[0] + 1) * (maxs[1] + 1) * (maxs[2] + 1));

        int ind = 0;
        if (isDouble) {
          for (int j = mins[2]; j <= maxs[2]; j++) {
            for (int i = mins[1]; i <= maxs[1]; i++) {
              for (int k = mins[0]; k <= maxs[0]; k++) {
                tempi = static_cast<vtkDoubleArray*>(coords[1])->GetValue(i)
                  * cos(static_cast<vtkDoubleArray*>(coords[2])->GetValue(j));
                tempj = static_cast<vtkDoubleArray*>(coords[1])->GetValue(i)
                  * sin(static_cast<vtkDoubleArray*>(coords[2])->GetValue(j));
                tempk = static_cast<vtkDoubleArray*>(coords[0])->GetValue(k);
                vpoints->SetPoint(ind, tempi, tempj, tempk);
                ind++;
              }
            }
          }
        } else if (isFloat) {
          for (int j = mins[2]; j <= maxs[2]; j++) {
            for (int i = mins[1]; i <= maxs[1]; i++) {
              for (int k = mins[0]; k <= maxs[0]; k++) {
                tempi = static_cast<vtkFloatArray*>(coords[1])->GetValue(i)
                  * cos(static_cast<vtkFloatArray*>(coords[2])->GetValue(j));
                tempj = static_cast<vtkFloatArray*>(coords[1])->GetValue(i)
                  * sin(static_cast<vtkFloatArray*>(coords[2])->GetValue(j));
                tempk = static_cast<vtkFloatArray*>(coords[0])->GetValue(k);
                vpoints->SetPoint(ind, tempi, tempj, tempk);
                ind++;
              }
            }
          }
        }

        // Create a Structured grid
        vtkStructuredGrid* sgrid = vtkStructuredGrid::New();
        sgrid->SetDimensions(&(gdims[0]));
        sgrid->SetPoints(vpoints);

        // Cleanup local data
        vpoints->Delete();

        // Cleanup local data
        for (size_t i = 0; i < vsdim; ++i) {
            coords[i]->Delete();
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Returning transformed data." << std::endl;
        return sgrid;
    }
}

// *****************************************************************************
//  Method: avtVsFileFormat::getStructuredMesh
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

vtkDataSet* avtVsFileFormat::getStructuredMesh(VsStructuredMesh* structuredMesh,
                                               bool haveDataSelections,
                                               int* mins, int* maxs,
                                               int* strides)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Find points: Structured meshes are datasets, and the data is
    // the points So, look for the dataset with the same name as the
    // mesh
    VsDataset* pointsDataset =
      registry->getDataset(structuredMesh->getFullName());

    if (pointsDataset == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Component '"
                          << structuredMesh->getFullName()
                          << "' not found.  Returning NULL." << std::endl;
        return NULL;
    }

    // ARS - Becasue of the way the data structures are used to hold
    // structured data in VTK and VisIt the topological dimension has
    // to equal the spatial dimension. That is ONLY the last dim(s) of
    // the nodes can be 1.
    size_t numSpatialDims = structuredMesh->getNumSpatialDims();
    size_t numTopologicalDims = structuredMesh->getNumTopologicalDims();

    // Get dims of points array
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Determining dimension of points array." << std::endl;

    std::vector<int> numNodes;
    structuredMesh->getNodeDims(numNodes);

    // VisIt downcasts to float, so go to float by default now.
    hid_t meshDataType = pointsDataset->getType();

    // Cache the data type because it's faster
    bool isDouble = isDoubleType(meshDataType);
    bool isFloat = isFloatType(meshDataType);

    if (!isDouble && !isFloat) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Error: hdf5 mesh data type not handled: "
                          << meshDataType << "Returning NULL." << std::endl;
        return NULL;
    }

    // Storage for meshes in VisIt, which is a vtkStructuredGrid which
    // is spatially 3D so the points must also be 3D.
    size_t vsdim = 3;
    std::vector<int> gdims(vsdim);

    // Adjust for the data selections which are NODAL. If no selection
    // the bounds are set to 0 and max with a stride of 1.
    GetSelectionBounds( numSpatialDims, numNodes, gdims,
                        mins, maxs, strides, haveDataSelections );

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
    if( !GetParallelDecomp( numSpatialDims, gdims, mins, maxs, strides ) )
      return NULL; // No work for this processor.

    haveDataSelections = 1;
#endif

    int numPoints = 1;
    for (size_t i=0; i<numSpatialDims; ++i)
      numPoints *= gdims[i];

    VsLog::debugLog() << CLASSFUNCLINE
    << "Total number of points is " << numPoints
    << std::endl;

    // Read points and add in zero for any lacking dimension
    size_t dsize = 0;
    void* dataPtr = 0;
    double* dblDataPtr = 0;
    float* fltDataPtr = 0;

    if (isDouble) {
        dsize = sizeof(double);
        dblDataPtr = new double[numPoints*3];
        dataPtr = dblDataPtr;
    }
    else if (isFloat) {
        dsize = sizeof(float);
        fltDataPtr = new float[numPoints*3];
        dataPtr = fltDataPtr;
    }

    if (!dataPtr) {
        VsLog::debugLog() << CLASSFUNCLINE
        << "Allocation failed, pointer is NULL.  "
        << "Returning NULL." << std::endl;
        return NULL;
    }

    // Read in the data
    herr_t err;

    if( haveDataSelections )
      err = reader->getData( pointsDataset, dataPtr,
                             // -1 read all coordinate components
                             structuredMesh->getIndexOrder(), -1,
                             mins, &(gdims[0]), strides );
    else
      err = reader->getData( pointsDataset, dataPtr );

    if (err < 0)
    {
        VsLog::debugLog() << CLASSFUNCLINE
        << "Error " << err
        << " while reading data.  Returning NULL." << std::endl;

        if (isDouble)
        delete [] dblDataPtr;
        else if (isFloat)
        delete [] fltDataPtr;

        return NULL;
    }

    // If spatial dimension is less than 3, move coordinates to the
    // correct position and set the extra dimensions to zero.
    if (numSpatialDims < 3)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Point spatial dimensionality ("
                          << numSpatialDims << " is less than 3.  "
                          << "Moving data into correct location." << std::endl;

        for (int i=numPoints-1; i>=0; --i)
        {
            unsigned char* destPtr
              = (unsigned char*) dataPtr + i*3*dsize;
            unsigned char* srcPtr
              = (unsigned char*) dataPtr + i*numSpatialDims*dsize;

            memmove(destPtr, srcPtr, numSpatialDims*dsize);
            destPtr += numSpatialDims*dsize;
            memset(destPtr, 0, (3-numSpatialDims)*dsize);
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Data move succeeded." << std::endl;
    }

    // Create the mesh and set its dimensions, including unused to zero
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Creating the mesh." << std::endl;

    // Add the points, changing to C ordering
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Adding points to mesh." << std::endl;

    vtkPoints* vpoints = vtkPoints::New();
    bool isFortranOrder = structuredMesh->isFortranOrder();

    if (isDouble) {
        // Note: must precede SetNumberOfPoints for alloc to succeed
        vpoints->SetDataTypeToDouble();
        vpoints->SetNumberOfPoints(numPoints);// will allocate

        VsLog::debugLog() << CLASSFUNCLINE
                          << " Adding " << numPoints << " with isFortranOrder = "
                          << isFortranOrder << ", type is double.\n";

        this->setStructuredMeshCoords(gdims, dblDataPtr, isFortranOrder, vpoints);
        delete [] dblDataPtr;
    }
    else if (isFloat) {
        // Note: must precede SetNumberOfPoints for alloc to succeed
        vpoints->SetDataTypeToFloat();
        vpoints->SetNumberOfPoints(numPoints);// will allocate

        VsLog::debugLog() << CLASSFUNCLINE
                          << " Adding " << numPoints << " with isFortranOrder = "
                          << isFortranOrder << ", type is float.\n";

        this->setStructuredMeshCoords(gdims, fltDataPtr, isFortranOrder, vpoints);
        delete [] fltDataPtr;
    }

    /*
     // debug: output points
     fltDataPtr = (float*)ptsPtr;
     dblDataPtr = (double*)ptsPtr;
     for (size_t i = 0; i < numPoints; ++i) {
     VsLog::debugLog() << i << ":";
     for (size_t j = 0; j < 3; ++j) {
     if (H5Tequal(type, H5T_NATIVE_DOUBLE)) {
     VsLog::debugLog() << " " << dblDataPtr[(3*i)+j];
     }
     else VsLog::debugLog() << " " << fltDataPtr[(3*i)+j];
     }
     VsLog::debugLog() << std::endl;
     }
     // end debug
     */
    vtkStructuredGrid* sgrid = vtkStructuredGrid::New();
    sgrid->SetDimensions(&(gdims[0]));
    sgrid->SetPoints(vpoints);

    std::string maskName = structuredMesh->getMaskName();
    if (maskName != "") {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Mask detected, name is " << maskName << std::endl;
        // To access the data
        VsDataset* mask = registry->getDataset(maskName);
        // To access the attributes
        VsVariable* maskVar = registry->getVariable(maskName);
        if (!mask || !maskVar) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Cannot access mask dataset "
                              << maskName << std::endl;
        }
        else {
            hid_t maskType = mask->getType();
            bool maskIsFortranOrder = maskVar->isFortranOrder();
            std::string maskCentering = maskVar->getCentering();

            // Masking array, we use the same technique used elsewhere to
            // turn off ghost nodes
            vtkUnsignedCharArray *maskedNodes = vtkUnsignedCharArray::New();
            // Must have the name "avtGhostNodes"
            maskedNodes->SetName("avtGhostNodes");
            maskedNodes->SetNumberOfTuples(numPoints);
            for (size_t k = 0; k < (size_t)numPoints; ++k) {
                // Zero means no masking, node is visible
                maskedNodes->SetValue(k, 0);
            }

            if (isDoubleType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type double." << std::endl;
                this->fillInMaskNodeArray<double>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else if (isFloatType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type float." << std::endl;
                this->fillInMaskNodeArray<float>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else if (isIntType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type int." << std::endl;
                this->fillInMaskNodeArray<int>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else if (isShortType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type short." << std::endl;
                this->fillInMaskNodeArray<short>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else if (isCharType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type char." << std::endl;
                this->fillInMaskNodeArray<char>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else if (isUnsignedCharType(maskType)) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of type unsigned char." << std::endl;
                this->fillInMaskNodeArray<unsigned char>(gdims, mask,
                        maskIsFortranOrder,
                        maskedNodes);
            }
            else {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Mask is of unsupported type." << std::endl;
            }
            sgrid->GetPointData()->AddArray(maskedNodes);
            maskedNodes->Delete();
        }
    }

    // Cleanup local data
    vpoints->Delete();

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Returning data." << std::endl;

    //This is the "alternate" way to attach information to a dataset in the VisIt pipeline.
    //It works for meshes, where the vtkInformation approach works for data
    //Kept for historical purposes
    //Attach offset information to dataset
    //debug5 <<"avtVsFileFormat::getStructuredMesh() - attaching node offset as field data." <<std::endl;
    //vtkDoubleArray* offsetArray = vtkDoubleArray::New();
    //offsetArray->SetNumberOfTuples(3);
    //offsetArray->SetValue(0, 0.1);
    //offsetArray->SetValue(1, 0.2);
    //offsetArray->SetValue(2, 0.3);
    //offsetArray->SetName("nodeOffset");
    //sgrid->GetFieldData()->AddArray(offsetArray);
    //offsetArray->Delete();

    return sgrid;
}

//Most of this really should be moved into the HighOrderUnstrucured class.
vtkDataSet*
avtVsFileFormat::getHighOrderUnstructuredMesh(VsUnstructuredMesh* unstructuredMesh,
                                              bool haveDataSelections,
                                              int* mins, int* maxs, int* strides) {
    VsLog::debugLog() << CLASSFUNCLINE << "Entering." << std::endl;

    LoadData();

    thisData.setReader(reader);
    thisData.setRegistry(registry);

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return thisData.getMesh(unstructuredMesh);
}

// *****************************************************************************
//  Method: avtVsFileFormat::getUnstructuredMesh
//
//  Purpose:
//      Request an unstructured mesh
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

vtkDataSet*
avtVsFileFormat::getUnstructuredMesh(VsUnstructuredMesh* unstructuredMesh,
                                     bool haveDataSelections,
                                     int* mins, int* maxs, int* strides)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Check for points type
    hid_t meshDataType = unstructuredMesh->getDataType();

    // Cache the data type because it's faster
    bool isDouble = isDoubleType(meshDataType);
    bool isFloat = isFloatType(meshDataType);

    if (!isDouble && !isFloat) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Error: hdf5 mesh data type not handled: "
                          << meshDataType << "Returning NULL." << std::endl;
        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Checking dimensionality of mesh." << std::endl;

    size_t numNodes       = unstructuredMesh->getNumPoints();
    size_t numSpatialDims = unstructuredMesh->getNumSpatialDims();

    // Get ready to read in points
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Setting up data structures." << std::endl;

    vtkUnstructuredGrid* ugridPtr = vtkUnstructuredGrid::New();

    // Create and set points while small so minimal memory usage
    vtkPoints* vpts = vtkPoints::New();
    ugridPtr->SetPoints(vpts);
    vpts->Delete();
    vtkPoints* vpoints = ugridPtr->GetPoints();

    // If there is no polygon data, then this mesh was registered as a
    // point mesh so only read in the points requested

    // Adjust for the data selections which are ZONAL.
    if (unstructuredMesh->isPointMesh() && haveDataSelections)
    {
        if( maxs[0] < 0 || numNodes - 1 < (size_t)maxs[0] )
          maxs[0] = (int) numNodes - 1;  // last cell index, not number of cells

        if( maxs[0] < mins[0] )
          mins[0] = 0;

        VsLog::debugLog()
          << CLASSFUNCLINE
          << "Have a zonal inclusive selection for unstructured point mesh "
          << "(" << mins[0] << "," << maxs[0] << " stride " << strides[0] << ") "
          << std::endl;

        // New number of nodes based on the above.
        numNodes = (maxs[0]-mins[0]) / strides[0] + 1;
    }

    // Allocate
    size_t dsize = 0;
    if (isDouble) {
        vpoints->SetDataTypeToDouble();
        dsize = sizeof(double);
    }
    else if (isFloat) {
        vpoints->SetDataTypeToFloat();
        dsize = sizeof(float);
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "VPoints array will have " << numNodes << " points."
                      << std::endl;

    vpoints->SetNumberOfPoints(numNodes);
    void* dataPtr = vpoints->GetVoidPointer(0);

    if (!dataPtr) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unable to allocate the points.  Cleaning up."
                          << std::endl;

        ugridPtr->Delete();

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Returning NULL." << std::endl;

        return NULL;
    }

    // Mesh points are in separate data sets.
    if (unstructuredMesh->usesSplitPoints())
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Using split-points method" << std::endl;

        // Kind of grim but read each of the coordinate components in
        // using the generic reader.

        // To do so set the location in memory where each cordinate
        // component will be stored.
        int srcMins[1] = {0};
        int srcMaxs[1] = {0};
        int srcStrides[1] = {0};

        if( haveDataSelections )
        {
            srcMins[0] = mins[0];
            srcMaxs[0] = (int)numNodes;
            srcStrides[0] = strides[0];
        }
        else
        {
            srcMins[0] = 0;
            srcMaxs[0] = (int)numNodes;
            srcStrides[0] = 1;
        }

        int destSize[1] = {(int)numNodes*3};
        int destMins[1] = {0};
        int destMaxs[1] = {(int)numNodes};
        int destStrides[1] = {3};

        for( size_t i=0; i<numSpatialDims; ++i )
        {
            VsDataset* pointDataset = unstructuredMesh->getPointsDataset((int)i);

            destMins[0] = (int)i;

            herr_t err = reader->getData(pointDataset, dataPtr,
                    unstructuredMesh->getIndexOrder(),
                    -2,
                    &srcMins[0], &srcMaxs[0], &srcStrides[0],
                    1, &destSize[0],
                    &destMins[0], &destMaxs[0], &destStrides[0] );

            if (err < 0) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Call to getDataSet returned error: "
                                  << err << "Returning NULL." << std::endl;

                return NULL;
            }
        }

        // The above stores the value in the correct location but make
        // sure the remaing values are all zero.
        for (size_t i=numSpatialDims; i<3; ++i)
        {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Zeroing data at unused positions."
                              << std::endl;

            if (isDouble) {

                double* dblDataPtr = &(((double*) dataPtr)[i]);

                for (size_t j=0; j<numNodes; ++j)
                {
                    *dblDataPtr = 0;
                    dblDataPtr += 3;
                }
            }
            else if (isFloat) {

                float* fltDataPtr = &(((float*) dataPtr)[i]);

                for (size_t j=0; j<numNodes; ++j)
                {
                    *fltDataPtr = 0;
                    fltDataPtr += 3;
                }
            }
        }
    }

    // Mesh points are in one data set.
    else
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Using all-in-one method" << std::endl;

        VsDataset* pointsDataset = unstructuredMesh->getPointsDataset();

        herr_t err;

        // If a point mesh and with data selections read in only the
        // points needed. If any other structured mesh read in all of
        // the points because it is not know which will be used to build
        // the cells.
        if (unstructuredMesh->isPointMesh() && haveDataSelections)
        {
            int srcMins[1] = {mins[0]};
            int srcMaxs[1] = {(int)numNodes};
            int srcStrides[1] = {strides[0]};

            err = reader->getData( pointsDataset, dataPtr,
                    // -1 read all coordinate components
                    unstructuredMesh->getIndexOrder(), -1,
                    &(srcMins[0]), &(srcMaxs[0]), &(srcStrides[0]) );
        }
        else
          err = reader->getData(pointsDataset, dataPtr);

        if (err < 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Call to getDataSet returned error: "
                              << err << "Returning NULL." << std::endl;

            return NULL;
        }

        // If spatial dimension is less than 3, move coordinates to the
        // correct position and set the extra dimensions to zero.
        if (numSpatialDims < 3)
        {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Point spatial dimensionality ("
                              << numSpatialDims << " is less than 3.  "
                              << "Moving data into correct location."
                              << std::endl;

            for (int i=numNodes-1; i>=0; --i)
            {
                unsigned char* destPtr =
                  (unsigned char*) dataPtr + i*3*dsize;
                unsigned char* srcPtr =
                  (unsigned char*) dataPtr + i*numSpatialDims*dsize;

                memmove(destPtr, srcPtr, numSpatialDims*dsize);
                destPtr += numSpatialDims*dsize;
                memset(destPtr, 0, (3-numSpatialDims)*dsize);
            }

            VsLog::debugLog() << CLASSFUNCLINE
                              << "Data move succeeded." << std::endl;
        }
    }

    // If there is no polygon data, then this mesh was registered as a
    // point mesh and we don't need to go any further
    if (unstructuredMesh->isPointMesh())
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Mesh was registered as a point mesh."
                          << "Because no connectivity data was found. "
                          << "Adding vertices as single points and returning."
                          << std::endl;

        vtkIdType vertex;

        for (size_t i=0; i<numNodes; ++i) {
            vertex = i;
            ugridPtr->InsertNextCell(VTK_VERTEX, 1, &vertex);
        }

        return ugridPtr;
    }

    // Next, look for connectivity data
    VsDataset* connectivityMeta = 0;

    unsigned int numTopologicalDims;
    unsigned int haveConnectivityCount = 0;
    std::string connectivityDatasetName;

    // For now users can have only one connectivity dataset.
    if( (connectivityMeta = unstructuredMesh->getLinesDataset())) {
        haveConnectivityCount = 2;
        numTopologicalDims = 2;
        connectivityDatasetName = unstructuredMesh->getLinesDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getPolygonsDataset()) ) {
        haveConnectivityCount = 0;
        numTopologicalDims = 2;
        connectivityDatasetName = unstructuredMesh->getPolygonsDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getTrianglesDataset()) ) {
        haveConnectivityCount = 3;
        numTopologicalDims = 2;
        connectivityDatasetName = unstructuredMesh->getTrianglesDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getQuadrilateralsDataset()) ) {
        haveConnectivityCount = 4;
        numTopologicalDims = 2;
        connectivityDatasetName = unstructuredMesh->getQuadrilateralsDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getPolyhedraDataset()) ) {
        haveConnectivityCount = 0;
        numTopologicalDims = 3;
        connectivityDatasetName = unstructuredMesh->getPolyhedraDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getTetrahedralsDataset()) ) {
        haveConnectivityCount = 4;
        numTopologicalDims = 3;
        connectivityDatasetName = unstructuredMesh->getTetrahedralsDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getPyramidsDataset()) ) {
        haveConnectivityCount = 5;
        numTopologicalDims = 3;
        connectivityDatasetName = unstructuredMesh->getPyramidsDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getPrismsDataset()) ) {
        haveConnectivityCount = 6;
        numTopologicalDims = 3;
        connectivityDatasetName = unstructuredMesh->getPrismsDatasetName();
    } else if( (connectivityMeta = unstructuredMesh->getHexahedralsDataset()) ) {
        haveConnectivityCount = 8;
        numTopologicalDims = 3;
        connectivityDatasetName = unstructuredMesh->getHexahedralsDatasetName();
    }

    else {
        VsLog::debugLog() << CLASSFUNCLINE
        << "ERROR - unable to find connectivity dataset. "
        << "Returning points data without connectivity."
        << std::endl;

        // We used to try to convert this into a pointMesh but it never
        // worked (Perhaps because the mesh was registered
        // differently. So instead give up.

//       vtkIdType vertex;
//       for (int i=0; i<numNodes; ++i) {
//         vertex = i;
//         ugridPtr->InsertNextCell(VTK_VERTEX, 1, &vertex);
//       }

        return ugridPtr;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Found connectivity data. "
                      << "Connectivity dataset name is "
                      << connectivityDatasetName << "  "
                      << "haveConnectivityCount = "
                      << haveConnectivityCount
                      << std::endl;

    std::vector<int> connectivityDims = connectivityMeta->getDims();

    size_t datasetLength = 1;
    for (size_t i = 0; i < connectivityDims.size(); ++i) {
        datasetLength *= connectivityDims[i];
    }

    // Vertices
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Allocating space for " << datasetLength
                      << " integers of connectivity data." << std::endl;

    int* vertices = new int[datasetLength];
    if (!vertices) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unable to allocate vertices.  Cleaning up."
                          << std::endl;

        ugridPtr->Delete();

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Returning NULL." << std::endl;

        return NULL;
    }

    VsDataset* connectivityDataset =
        registry->getDataset(connectivityDatasetName);

    // Adjust for the data selections which are ZONAL which will limit
    // which connections are read in.
    size_t numCells, numVerts;
    if( unstructuredMesh->isCompMajor() ) {
        numCells = connectivityDims[1];
        numVerts = connectivityDims[0];
    }
    else {
        numCells = connectivityDims[0];
        numVerts = connectivityDims[1];
    }

    // Adjust for the data selections which are ZONAL which will limit
    // which connections are read in.
    if (haveDataSelections) {
        if( maxs[0] < 0 || numCells - 1 < (size_t)maxs[0] )
          maxs[0] = (int) numCells - 1; // numCells - 1 = last cell index,
                                        // not number of cells

        if( maxs[0] < mins[0] )
            mins[0] = 0;

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Have a zonal inclusive selection for unstructured mesh cells "
                          << "(" << mins[0] << "," << maxs[0] << " stride " << strides[0] << ") "
                          << std::endl;

        // New number of cells based on the above.
        numCells = (maxs[0]-mins[0]) / strides[0] + 1;
    }

    // Polyhedra load as 1D packed array
    // Polygons support old 2D array and new 1D packed array format
    // Determine if we are packing
    // For polygons we detect backwards compatibility by checking
    // if connectivityDims[0] = 1 or connectivityDims[1] = 1 (means it is a packed 1D array)

    bool bUseCompressedPolygonsOrPolyhedraFormat =
        (haveConnectivityCount == 0) && // this means Polygons or Polyhedra
        !haveDataSelections && // only use this when haveDataSelections is false
        ((numTopologicalDims != 2) || (connectivityDims[0] == 1) || (connectivityDims[1] == 1)); // to support backwards compatibility for polygons

    // Here the connections are being read. So sub select if needed.
    size_t k = 0;
    herr_t loadDataErr;
    if (haveDataSelections) {
        int srcMins[1] = {mins[0]};
        int srcMaxs[1] = {static_cast<int>(numCells)};
        int srcStrides[1] = {strides[0]};

        loadDataErr = reader->getData( connectivityDataset, vertices,
                // -1 read all coordinate components
                unstructuredMesh->getIndexOrder(), -1,
                &(srcMins[0]), &(srcMaxs[0]), &(srcStrides[0]) );
    }
    else {
        loadDataErr = reader->getData(connectivityDataset, vertices);

        // There is 1 awkward edge case we can only determine now that
        // we loaded data Old format polygons which were just 1
        // polygon. That would make above
        // bUseCompressedPolygonsOrPolyhedraFormat be set true
        // incorrectly.  This can be safely detected by checking if
        // the first element is equal to the data length + 1. Then
        // logically it must be old format.  Note this works and was
        // tested but for some reason visit loaded a single poly with
        // a long delay (after this function exits) and did not
        // investigate that yet

        if ((haveConnectivityCount == 0) &&
            (numTopologicalDims == 2) && (datasetLength == vertices[0]+1)) {
            bUseCompressedPolygonsOrPolyhedraFormat = false; // cancel compression
        }

        if (bUseCompressedPolygonsOrPolyhedraFormat) {
            numCells = vertices[k++];  // numCells is packed array 1st element
            numVerts = -1;  // special handling
        }
    }


    // Log some debug info
    VsLog::debugLog() << CLASSFUNCLINE
                      << "numCells = " << numCells
                      << ", numVerts = " << numVerts << "." << std::endl;

    // Check for connectivity list type
    if (!isIntType( connectivityMeta->getType() )) {
        VsLog::debugLog() << CLASSFUNCLINE
        << "Indices are not integers. Cleaning up" << std::endl;

        ugridPtr->Delete();

        VsLog::debugLog() << CLASSFUNCLINE
        << "Returning NULL" << std::endl;

        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
    << "Reading connectivity list data." << std::endl;

    if (loadDataErr < 0) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Call to getDataSet returned error: " << loadDataErr
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    try {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Allocating " << numCells << " cells.  "
                          << "If old VTK and this fails, it will just abort."
                          << std::endl;

        ugridPtr->Allocate(numCells);
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Allocation succeeded." << std::endl;
    }
    // JRC: what goes here to detect failure to allocate?
    catch (std::bad_alloc) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Caught std::bad_alloc exception. "
                          << "Unable to allocate space for cells.  Cleaning up."
                          << "Returning NULL." << std::endl;

        delete [] vertices;
        ugridPtr->Delete();

        return NULL;
    } catch (...) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unknown exception allocating cells.  Cleaning up."
                          << "Returning NULL." << std::endl;

        delete [] vertices;
        ugridPtr->Delete();

        return NULL;
    }

    // Tweak for USim 

    // Prepare to fix up the connectivity list if node correction data
    // is available
    int* correctionList = NULL;
    size_t correctionListSize = 0;
    if (unstructuredMesh->hasNodeCorrectionData()) {
        VsDataset* correctionDataset = registry->getDataset(unstructuredMesh->getNodeCorrectionDatasetName());
        if (correctionDataset) {
            correctionListSize = correctionDataset->getLength();
            int* localToGlobalNodeMapping = new int[correctionListSize]; // Memory leak?
            reader->getData(correctionDataset, localToGlobalNodeMapping);

            // Build up a list of which global ids are "taken" by more
            // than one node And when that happens, remember the local
            // ids that need to be mapped to the original local id
            correctionList = new int[correctionListSize];
            int* globalToLocalNodeMapping = new int[correctionListSize];
            for (size_t i = 0; i < correctionListSize; i++) {
                correctionList[i] = -1;
                globalToLocalNodeMapping[i] = -1;
            }

            // Build up the correction list
            for (int i = 0; i < (int)correctionListSize; i++) {
                int localId = i;
                int globalId = localToGlobalNodeMapping[i];
                if (globalToLocalNodeMapping[globalId] != -1) {
                    //VsLog::debugLog() <<"Global id " <<globalId <<" is already taken by local node " <<globalToLocalNodeMapping[globalId] <<" so we know that node " <<i <<" should be replaced by node " <<globalToLocalNodeMapping[globalId] <<std::endl;
                    correctionList[i] = globalToLocalNodeMapping[globalId];
                } else {
                    //VsLog::debugLog() <<"Local id " <<localId <<" is claiming global id " <<globalId <<std::endl;
                    globalToLocalNodeMapping[globalId] = localId;
                }
            }
        }
    }
    //end tweak

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Inserting cells into grid." << std::endl;

    int warningCount = 0;
    int cellCount = 0;
    unsigned int cellVerts = 0; // total verts (for VTK_POLYHEDRON this value is not topologically meaningful - see below)
    unsigned int cellFaces = 0; // VTK_POLYHEDRON calls InsertNextCell passing face count, not vertex count
    int cellType;

    // Dealing with fixed length connectivity lists.
    if( haveConnectivityCount ) {
        cellVerts = haveConnectivityCount;
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Inserting " << cellVerts
                          << " vertices into each cell." << std::endl;
    }

    for (size_t i = 0; i < numCells; ++i) {
        if (k >= datasetLength) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "While iterating over the vertices, "
                              << "the index variable 'k' "
                              << "went beyond the end of the array. "
                              << "Existing cells will be returned "
                              << "but the loop is terminating now." << std::endl;
            break;
        }

        ++cellCount;

        // Dealing with cells with variable number of vertices.
        if (haveConnectivityCount == 0) {
            // Polygons are loaded as a list C N1 i j k N2 i j k l N3 ...
            // but may also be loaded as old 2D array for backwards compatibility
            // Polyhedra are loaded as list C F1 L1 N1 i j k N2 i j k l F2 L2 N1 i j k l m N2 i j k ...
            // C is the number of cells for packed mode
            // Polyhedra have F1, F2 etc to indicate number of faces which is passed to InsertNextCell, not vertex count
            if (numTopologicalDims == 3) {  // Polyhedra always use the compressed 1D array
                cellFaces = vertices[k++];  // Read in the face count (F1, F2, ...)
            }
            cellVerts = vertices[k++]; // This is correct for Polyhedra and Polygons (old and new format)
        }

        if (cellVerts > numVerts) {
            // funny, the number of cells exceeds the length of the line
            // this must be an error
            // we will drop back to adding individual vertices
            cellVerts = 0;
        }

        // for the special case of VTK_POLYHEDRON do not run the switch on cellVerts
        // cellVerts is an array length which does not correspond to any topology
        // For numTopologicalDims = 2 (VTK_POLYGON) cellVerts is ok
        if (haveConnectivityCount == 0 && numTopologicalDims == 3) {
            cellType = VTK_POLYHEDRON;
        }
        else
        {
          switch (cellVerts) {
            case 1:
              cellType = VTK_VERTEX;
            break;
            case 2:
              cellType = VTK_LINE;
            break;
            case 3:
              cellType = VTK_TRIANGLE;
              break;
            case 4:
              if( numTopologicalDims == 2 ) cellType = VTK_QUAD;
              else if( numTopologicalDims == 3 ) cellType = VTK_TETRA;
            break;
            case 5:
              if( numTopologicalDims == 2 ) cellType = VTK_POLYGON;
              else if( numTopologicalDims == 3 ) cellType = VTK_PYRAMID;
              break;
            case 6:
              if( numTopologicalDims == 2 ) cellType = VTK_POLYGON;
              else if( numTopologicalDims == 3 ) cellType = VTK_WEDGE;
              break;
            case 8:
              if( numTopologicalDims == 2 ) cellType = VTK_POLYGON;
              else if( numTopologicalDims == 3 ) cellType = VTK_HEXAHEDRON;
            break;
            default:
              if (numTopologicalDims == 2) cellType = VTK_POLYGON;
              else {
                if (warningCount < 30) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Error: invalid number of vertices for cell #"
                                      << cellCount << ": " << cellVerts << std::endl;
                } else if (warningCount == 30) {
                  VsLog::debugLog() << CLASSFUNCLINE
                                    << "Exceeded maximum number of errors.  "
                                    << "Error messages disabled for remaining cells."
                                    << std::endl;
                }

                ++warningCount;
                cellType = VTK_EMPTY_CELL;
            }
            break;
            }
        }

        bool newStyle = true;

        /* Old style used by USim has the dimensions of the cells datasets  = (number of cells, number of points in the cell).  
        For example, the hex mesh:
        DATASET "cells" {
            DATATYPE  H5T_STD_I32LE
            DATASPACE  SIMPLE { ( 2008, 8 ) / ( 2008, 8 ) }
            DATA {
            (0,0): 291, 605, 460, 288, 728, 776, 668, 575,
            
        The new style used by VSim has the dimensions of the cells dataset = (number of cells, number of points in the cell + 1) with the first index showing how many indices should be taken 
        into account.  For example, the tet mesh is
        DATASET "cells" {
         DATATYPE  H5T_STD_I32LE
         DATASPACE  SIMPLE { ( 3634, 5 ) / ( 3634, 5 ) }
         DATA {
         (0,0): 4, 797, 701, 674, 703,
         (1,0): 4, 722, 244, 609, 750,

        If we use the new style, we need to skip the first index when creating vertices.  
        */
        if (haveConnectivityCount == connectivityDims[1]) newStyle = false;

        // Create cell and insert into mesh
        if (cellType != VTK_EMPTY_CELL) {
            std::vector<vtkIdType> verts(cellVerts);
            for (size_t j = 0; j < cellVerts; ++j) {
                size_t kk = k++;
                // This correction is only for volume meshes
                if ((newStyle) && (numTopologicalDims == 3)) {
                  // Skip the first index in the row
                  if (kk%(haveConnectivityCount+1) == 0) { 
                    j = j-1;
                    continue;
                  }  
                }  
                verts[j] = (vtkIdType) vertices[kk];
                if ((verts[j] < 0) || ((size_t)verts[j] >= numNodes)) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "ERROR in connectivity dataset - requested vertex number "
                                      << verts[j] << " exceeds number of vertices" << std::endl;

                    verts[j] = 0;
                }
            }

            // Tweak for USim
            // Apply node corrections
            if (correctionList) {
                for (size_t j = 0; j < cellVerts; j++) {
                    if ((verts[j] >= 0) && (verts[j] < (int)correctionListSize)) {
                        vtkIdType localVertexId = verts[j];
                        vtkIdType newId = correctionList[localVertexId];
                        if (newId != -1) {
                            //VsLog::debugLog() <<"Node #" <<localVertexId <<" should be switched to local id " <<newId <<std::endl;
                            verts[j] = newId;
                        }
                    }
                }
            }
            // end tweak

            if ((haveConnectivityCount == 0) && !bUseCompressedPolygonsOrPolyhedraFormat) {
                k += (numVerts - 1 - cellVerts);  // backwards compatibility mode for Polygons
            }

            // Insert cell into mesh - note that for InsertNextCell,
            // VTK_POLYHEDRON type takes face count, not vertex count
            vtkIdType cellOrFaceCount =
              (cellType == VTK_POLYHEDRON) ? cellFaces : cellVerts;

            ugridPtr->InsertNextCell(cellType, cellOrFaceCount, &verts[0]);
        }
        else {
            // There was some error so add each vertex as a single point.
            // NO!  Unless we've registered as a pointmesh, adding single
            // points won't work so we treat the entire row of the dataset
            // as a single cell Maybe something will work!
            std::vector<vtkIdType> verts(numVerts);
            k--;
            for (size_t j = 0; j < numVerts; ++j) {
                if (warningCount < 30) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "WARNING: ADDING cell #"
                                      << cellCount << " as cell: "
                                      << vertices[k] << std::endl;
                }
                verts[j] = (vtkIdType) vertices[k++];
            }
            ugridPtr->InsertNextCell (VTK_POLYGON, numVerts, &verts[0]);
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Finished.  Cleaning up." << std::endl;
    // Done, so clean up memory and return
    delete [] vertices;

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return ugridPtr;
}

// *****************************************************************************
//  Method: avtVsFileFormat::getPointMesh
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

vtkDataSet* avtVsFileFormat::getPointMesh(VsVariableWithMesh* variableWithMesh,
                                          bool haveDataSelections,
                                          int* mins, int* maxs, int* strides,
                                          bool transform)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    hid_t meshDataType = variableWithMesh->getType();

    // Cache the data type because it's faster
    bool isDouble = isDoubleType(meshDataType);
    bool isFloat = isFloatType(meshDataType);

    if (!isDouble && !isFloat) {
        VsLog::debugLog() << CLASSFUNCLINE
        << "Error: hdf5 mesh data type not handled: "
        << meshDataType << "Returning NULL." << std::endl;
        return NULL;
    }

    // Get the number of values
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Getting the number of points." << std::endl;

    size_t numSpatialDims     = variableWithMesh->getNumSpatialDims();
    size_t numTopologicalDims = variableWithMesh->getNumTopologicalDims();
    size_t numLogicalDims     = 1;

    std::vector<int> numNodes(numLogicalDims);
    numNodes[0] = (int)variableWithMesh->getNumPoints();

    // Storage for meshes in VisIt, which is a vtkRectilinearGrid which
    // is topologically 3D so the points must also be 3D.
    size_t vsdim = numLogicalDims;
    std::vector<int> gdims(vsdim);

    // Adjust for the data selections which are NODAL. If no selection
    // the bounds are set to 0 and max with a stride of 1.
    GetSelectionBounds( numLogicalDims, numNodes, gdims,
                        mins, maxs, strides, haveDataSelections, false );

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
    if( !GetParallelDecomp( numLogicalDims, gdims, mins, maxs, strides, 0 ) )
      return NULL; // No work for this processor.

    haveDataSelections = 1;
#endif

    // Read in points
    int numPoints = gdims[0];

    // Create the unstructured meshPtr
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Creating the vtkUnstructuredGrid." << std::endl;
    vtkUnstructuredGrid* meshPtr = vtkUnstructuredGrid::New();

    // Create and set points while small so minimal memory usage
    vtkPoints* vpts = vtkPoints::New();
    meshPtr->SetPoints(vpts);
    vpts->Delete();
    vtkPoints* vpoints = meshPtr->GetPoints();

    // Allocate
    size_t dsize = 0; (void) dsize;
    if (isDouble) {
        vpoints->SetDataTypeToDouble();
        dsize = sizeof(double);
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Double data" << std::endl;
    }
    else if (isFloat) {
        vpoints->SetDataTypeToFloat();
        dsize = sizeof(float);
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Float data" << std::endl;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Allocating for " << numPoints << " values." << std::endl;
    vpoints->SetNumberOfPoints(numPoints);

    void* dataPtr = vpoints->GetVoidPointer(0);
    if (!dataPtr) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unable to allocate the points.  Cleaning up."
                          << "Returning NULL." << std::endl;
        meshPtr->Delete();
        return NULL;
    }

    herr_t err;

    // Read in the data
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Reading data." << std::endl;

    // Kind of grim but read each of the coordinate components in
    // using the generic reader.

    // To do so set the location in memory where each cordinate
    // componenet will be stored.
    int srcMins[1] = {mins[0]};
    int srcMaxs[1] = {numPoints};
    int srcStrides[1] = {strides[0]};

    int destSize[1] = {gdims[0]*3};
    int destMins[1] = {0};
    int destMaxs[1] = {gdims[0]};
    int destStrides[1] = {3};

    for (unsigned int i= 0; i< numSpatialDims; i++)
    {
        int componentIndex = variableWithMesh->getSpatialDim(i);

        destMins[0] = i;

        VsDataset* variableDataset =
        registry->getDataset(variableWithMesh->getFullName());

        err = reader->getData(variableDataset, dataPtr,
                              variableWithMesh->getIndexOrder(),
                              componentIndex,
                              &srcMins[0], &srcMaxs[0], &srcStrides[0],
                              1, &destSize[0],
                              &destMins[0], &destMaxs[0], &destStrides[0] );

        if (err < 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Call to getVarWithMeshMeta returned error: "
                              << err << "Returning NULL." << std::endl;
            return NULL;
        }
    }

    // The above stores the value in the correct location but make
    // sure the remaining values are all zero.
    for (size_t i=numSpatialDims; i<3; ++i)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Zeroing data at unused positions." << std::endl;

        if (isDouble) {
            double* dblDataPtr = &(((double*) dataPtr)[i]);

            for (int j=0; j<gdims[0]; ++j)
            {
                *dblDataPtr = 0;
                dblDataPtr += 3;
            }
        }
        else if (isFloat) {
            float* fltDataPtr = &(((float*) dataPtr)[i]);

            for (int j=0; j<gdims[0]; ++j)
            {
                *fltDataPtr = 0;
                fltDataPtr += 3;
            }
        }
    }

    //If a transform is requested, do it
    //Note that we only have a 3d transform available right now
    if (transform && (numSpatialDims == 3)) {
        VsLog::debugLog() <<"Creating transformed point mesh." <<std::endl;
        if (isDouble) {
            double* dblDataPtr = (double*)dataPtr;

            for (int i = 0; i < gdims[0]; i++) {
                int baseIndex = i * 3;
                //Get original values
                double zValue = dblDataPtr[baseIndex];
                double rValue = dblDataPtr[baseIndex + 1];
                double phiValue = dblDataPtr[baseIndex + 2];

                //Calculate transform (remember, Z = Z)
                double xValue = rValue * cos(phiValue);
                double yValue = rValue * sin(phiValue);

                //Debugging output
                //VsLog::debugLog() <<"Transforming point " <<i <<" z = " <<zValue <<" r = " <<rValue <<" phi = " <<phiValue <<std::endl;
                //VsLog::debugLog() <<"Transforming point " <<i <<" x = " <<xValue <<" y = " <<yValue <<" z = "   <<zValue   <<std::endl;

                //Replace old values with new values
                dblDataPtr[baseIndex] = xValue;
                dblDataPtr[baseIndex+1] = yValue;
                dblDataPtr[baseIndex+2] = zValue;
            }
        } else if (isFloat) {
            float* fltDataPtr = (float*)dataPtr;

            for (int i = 0; i < gdims[0]; i++) {
                int baseIndex = i * 3;
                //Get original values
                float zValue = fltDataPtr[baseIndex];
                float rValue = fltDataPtr[baseIndex + 1];
                float phiValue = fltDataPtr[baseIndex + 2];

                //Calculate transform (remember, Z = Z)
                float xValue = rValue * cos(phiValue);
                float yValue = rValue * sin(phiValue);

                //Debugging output
                //VsLog::debugLog() <<"Transforming point " <<i <<" z = " <<zValue <<" r = " <<rValue <<" phi = " <<phiValue <<std::endl;
                //VsLog::debugLog() <<"Transforming point " <<i <<" x = " <<xValue <<" y = " <<yValue <<" z = "   <<zValue   <<std::endl;

                //Replace old values with new values
                fltDataPtr[baseIndex] = xValue;
                fltDataPtr[baseIndex+1] = yValue;
                fltDataPtr[baseIndex+2] = zValue;
            }
        }
    }

    // create point mesh
    try {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Allocating " << gdims[0]
                          << " vertices.  If old VTK and this fails, it will just abort." << std::endl;
        meshPtr->Allocate(gdims[0]);
    } catch (std::bad_alloc) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Caught std::bad_alloc. Unable to allocate cells."
                          << "Returning NULL." << std::endl;
        meshPtr->Delete();
        return NULL;
    } catch (...) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unknown exception. Unable to allocate cells."
                          << "Returning NULL." << std::endl;
        meshPtr->Delete();
        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
    << "Allocation succeeded.  Setting mesh to connectivity 'VERTEX'." << std::endl;
    vtkIdType vertex;
    for (int i=0; i<gdims[0]; ++i) {
        vertex = i;
        meshPtr->InsertNextCell(VTK_VERTEX, 1, &vertex);
    }

    // Clean up memory

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return meshPtr;
}

// *****************************************************************************
//  Method: avtVsFileFormat::getCurve
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
vtkDataSet* avtVsFileFormat::getCurve(int domain,
                                      const std::string& requestedName)
{
    // TODO - make "cleanupAndReturnNull" label, and do a "go to"
    // instead of just returning NULL all the time.

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Save the original name in a temporary variable
    // so that we can do some string manipulation on it
    std::string name = requestedName;

    ///TODO: This method piggybacks on getVar and getMesh -
    ///       Could be made much more efficient
    // 1. get var
    // 2. get matching mesh
    // 3. create 2 coord arrays - x from mesh and y from var
    // 4. Combine coord arrays to form 1-d Rectilinear mesh

    // Attempts to follow visit plugin Curve2d in
    // ./visit/src/databases/Curve2d/avtCurve2DFileFormat.C

    // Retrieve var metadata and extract the mesh name
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Looking for variable metadata." << std::endl;
    VsVariable* varMeta = registry->getVariable(name);

    if (varMeta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "No variable metadata found under name "
                          << name << "  "
                          << "Looking for information in component registry."
                          << std::endl;

        // Is this variable a component?  If so, swap the component
        // name with the "real" variable name and remember that it is
        // a component.
        bool isAComponent = false; (void) isAComponent;
        int componentIndex = -2; // No components
        NamePair foundName;
        registry->getComponentInfo(name, &foundName);

        if (!foundName.first.empty()) {
          name = foundName.first.c_str();
          varMeta = registry->getVariable(foundName.first);
          componentIndex = foundName.second;
          isAComponent = true;

          VsLog::debugLog() << CLASSFUNCLINE
                            << "Found a component, which refers to variable "
                            << name << " and index " << componentIndex
                            << std::endl;
        }
    }

    if (varMeta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Failed to find variable in component list.  "
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    hid_t varDataType = varMeta->getType();

    if (isDoubleType(varDataType)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Var is 64-bit real" << std::endl;
    } else if (isFloatType(varDataType)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Var is 32-bit real" << std::endl;
    } else if (isIntType(varDataType)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Var is int" << std::endl;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Var is type is not double, float, or int.  "
                          << "Returning NULL" << std::endl;
        return NULL;
    }

    vtkDataArray* varData = NULL;
    try {
        varData = GetVar(domain, requestedName.c_str());
    } catch (...) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Caught exception from GetVar().  "
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    if (varData == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Failed to load var data.  "
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    // Have the variable now get the mesh.
    std::string meshName = varMeta->getMeshName();
    VsMesh* meshMeta = varMeta->getMesh();

    if (meshMeta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "No mesh metadata found.  "
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    vtkDataSet* meshData = NULL;
    try {
        meshData = GetMesh(domain, meshName.c_str());
    } catch (...) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Caught exception from GetMesh().  "
                          << "Returning NULL."
                          << std::endl;
        varData->Delete();
        return NULL;
    }

    if (meshData == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Failed to load mesh data.  "
                          << "Returning NULL." << std::endl;
        varData->Delete();
        return NULL;
    }

    // Get the number of points on the curve.
    int nPts;

    if (varMeta->isCompMinor()) {
      nPts = varMeta->getDims()[0];
    } else {
      nPts = varMeta->getDims()[1];
    }

    // Cross-reference against the number of points in the mesh
    std::vector<int> meshDims;
    meshMeta->getCellDims(meshDims);

    int nPtsInMesh;
    if (varMeta->isZonal())
      nPtsInMesh = meshDims[0];      // Get the number of cells.
    else
      nPtsInMesh = meshDims[0] + 1;  // Get the number of nodes.

    int nPtsInOutput;
    if (nPts == nPtsInMesh) {
      nPtsInOutput = nPts;
    }
    else {
      VsLog::debugLog() << CLASSFUNCLINE
                        << "ERROR - mesh and var dimensionas don't match."
                        << std::endl;

      // Use the lower of the two values
      if (nPts < nPtsInMesh)
        nPtsInOutput = nPts;
      else
        nPtsInOutput = nPtsInMesh;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Variable has " << nPts << " points." << std::endl;
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Mesh has " << nPtsInMesh << " points." << std::endl;
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Output will have " << nPtsInOutput << " points."
                      << std::endl;

    // Create 1D RectilinearGrid
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Building Rectilinear grid." << std::endl;

    vtkFloatArray* vals = vtkFloatArray::New();
    vals->SetNumberOfComponents(1);
    vals->SetNumberOfTuples(nPtsInOutput);
    vals->SetName(requestedName.c_str());

    vtkRectilinearGrid* rg =
      vtkVisItUtility::Create1DRGrid(nPtsInOutput, VTK_FLOAT);
    rg->GetPointData()->SetScalars(vals);

    vtkFloatArray* xc = vtkFloatArray::SafeDownCast(rg->GetXCoordinates());

    vtkRectilinearGrid* meshDataRect =
    dynamic_cast<vtkRectilinearGrid*>(meshData);

    if (meshDataRect) {
        //Handles the incoming mesh as a rectilinear mesh
        vtkDataArray* meshXCoord = meshDataRect->GetXCoordinates();

        for (int i = 0; i < nPtsInOutput; i++) {
            double* var_i = varData->GetTuple(i);
            double* mesh_i = meshXCoord->GetTuple(i);

            xc->SetValue(i, mesh_i[0]);
            vals->SetValue(i, var_i[0]);
        }
    } else {
        //Handles the incoming mesh as a structured mesh
        vtkStructuredGrid* meshDataStructuredGrid =
          dynamic_cast<vtkStructuredGrid*>(meshData);

        if (!meshDataStructuredGrid) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Unable to extract points from mesh to construct curve.  "
                              << "Giving up." << std::endl;
            vals->Delete();

            return NULL;
        }

        vtkPoints* points = meshDataStructuredGrid->GetPoints();

        for (int i = 0; i < nPtsInOutput; i++) {
            double* var_i = varData->GetTuple(i);
            double* mesh_i = points->GetPoint(i);

            xc->SetValue(i, mesh_i[0]);
            vals->SetValue(i, var_i[0]);
        }
    }

    // Done, so clean up memory and return.
    meshData->Delete();
    varData->Delete();
    vals->Delete();

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return rg;
}

// *****************************************************************************
//  Method: avtVsFileFormat::nameIsComponent
//
//  Purpose:
//    If this variable a component swap the component name with the
//    "real" variable name and remember that it is a component.
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
bool avtVsFileFormat::nameIsComponent(std::string& name, int& componentIndex) {

    bool isAComponent = false;
    // int componentIndex = -2; // No components
    NamePair foundName;
    registry->getComponentInfo(name, &foundName);

    if (!foundName.first.empty()) {
        name = foundName.first.c_str();
        componentIndex = foundName.second;
        isAComponent = true;

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found a component, which refers to variable "
                          << name << " and index " << componentIndex
                          << std::endl;
    }

    return isAComponent;
}

// *****************************************************************************
//  Method: avtVsFileFormat::isTransformedName
//
//  Purpose:
//    Check if this var name is a transformed var name. If
//    so, use the original var name to get data associated
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
bool avtVsFileFormat::isTransformedName(std::string& name) {

    bool transform = false;
    std::string origVarName = registry->getOriginalVarName(name);

    if (!origVarName.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Original var for the transformed var "
                          << name << " is " << origVarName << std::endl;
        transform = true;
        name = origVarName;

    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unable to find an original var for the possible transform name "
                          << name <<std::endl;
    }

    return transform;
}

// *****************************************************************************
//  Method: avtVsFileFormat::StandardVar
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
vtkDataArray* avtVsFileFormat::StandardVar(int domain,
                                           const char* requestedName)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Save the original name in a temporary variable so that we can
    // do some string manipulation on it
    std::string name = requestedName;

    bool haveDataSelections;
    int mins[3], maxs[3], strides[3];

    // Adjust for the data selections which are NODAL (typical) or ZONAL.
    if( (haveDataSelections = ProcessDataSelections(mins, maxs, strides)) )
    {
        ///TODO: check on fix for assignment

        VsLog::debugLog()
          << CLASSFUNCLINE
          << "Have a data selection for variable " << name << "  "
          << "(" << mins[0] << "," << maxs[0] << " stride " << strides[0] << ") "
          << "(" << mins[1] << "," << maxs[1] << " stride " << strides[1] << ") "
          << "(" << mins[2] << "," << maxs[2] << " stride " << strides[2] << ") "
          << std::endl;
    }

    int componentIndex = -2; // No components
    bool isAComponent = nameIsComponent(name, componentIndex);
    bool transform = isTransformedName(name); (void) transform;

    // The goal in all of the metadata loading is to fill one of
    // these two variables:
    VsVariable* meta = NULL;
    VsVariableWithMesh* vmMeta = NULL;
    VsDataset* variableDataset = NULL;

    // If a MD variable retrieve the md metadata, look up the "real"
    // variable name using the domain number, and replace "name" with
    // the name of that variable.
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Checking for possible MD var." << std::endl;

    VsMDVariable* mdMeta = registry->getMDVariable(name);

    if (mdMeta) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found MD metadata for this name: "
                          << name << std::endl;

        if (0 <= domain && (size_t)domain < mdMeta->getNumBlocks()) {
            meta = mdMeta->getBlock(domain);
            name = meta->getFullName();

            if( meta )
            variableDataset = registry->getDataset(meta->getFullName());

        } else {
            VsLog::warningLog()
              << CLASSFUNCLINE
              << "Requested domain number is out of bounds for this variable."
              << std::endl;
        }
    }

    // No meta data so, look for a "regular" variable with this name.
    if (meta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Looking for regular (non-md) variable." << std::endl;
        meta = registry->getVariable(name);

        if( meta )
          variableDataset = registry->getDataset(meta->getFullName());
    }

    // No meta data so, look for a VarWithMesh with this name.
    if (meta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Looking for VarWithMesh variable." << std::endl;

        vmMeta = registry->getVariableWithMesh(name);

        if( vmMeta )
          variableDataset = registry->getDataset(vmMeta->getFullName());
    }

    // Haven't found metadata yet, so give up.
    if ((meta == NULL) && (vmMeta == NULL)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "ERROR: Could not find metadata for name: "
                          << name << std::endl;
        // DEBUG CODE
        //       std::vector<std::string> varNames;
        //       registry->getAllVariableNames(varNames);
        //       VsLog::debugLog() << CLASSFUNCLINE
        //                         << "All available names = ";
        //       for (unsigned int i = 0; i < varNames.size(); i++) {
        //         VsLog::debugLog() << varNames[i] << ", ";
        //       }
        //       VsLog::debugLog() << std::endl;
        //       VsLog::debugLog() << "Returning NULL" << std::endl;
        // END DEBUG
        return NULL;
    }

    // Have metadata from the variable, so load some info and look for
    // the mesh.
    hid_t varType = 0;
    std::vector<int> varDims;
    bool isFortranOrder = false;
    bool isCompMajor = false;
    bool isZonal = false;
    bool parallelRead = true; (void) parallelRead;
    bool hasOffset = false;
    std::vector<double> offset(3, 0);
    std::string indexOrder;

    size_t numTopologicalDims;
    size_t numLogicalDims;

    // VarWithMesh variable - Note that there is no mesh metadata for
    // VarWithMesh.
    if (vmMeta) {
        varDims = vmMeta->getDims();
        varType = vmMeta->getType();

        isZonal = true;

        indexOrder = vmMeta->getIndexOrder();
        isCompMajor = vmMeta->isCompMajor();

        numTopologicalDims = vmMeta->getNumTopologicalDims();
        numLogicalDims = 1;
        numTopologicalDims = 1;

        // For a VarWithMesh the varDims.size() will be 2 and the
        // variable will be a component while the logical dims will be
        // 1 as the values are nodal/zonal (for point clouds nodal==zonal).
        if (varDims.size() - (int) isAComponent != numLogicalDims )
        {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "WARNING: The variable and the mesh do not "
                              << "have the same logical dimension. "
                              // << "Returning NULL."
                              << std::endl;
            // return NULL;
        }
    }

    else {
        varDims = meta->getDims();
        varType = meta->getType();

        if (meta->isFortranOrder())
          isFortranOrder = true;

        if (meta->isZonal())
          isZonal = true;

        if (meta->hasNodeOffset()) {
            hasOffset = true;
            offset = meta->getNodeOffset();
        }

        indexOrder = meta->getIndexOrder();
        isCompMajor = meta->isCompMajor();

        std::string meshName = meta->getMeshName();

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Mesh for variable is '" << meshName << "'. "
                          << "Getting metadata for mesh." << std::endl;

        VsMesh* meshMetaPtr = registry->getMesh(meshName);

        numTopologicalDims = meshMetaPtr->getNumTopologicalDims();

        if( meshMetaPtr->isUnstructuredMesh() )
          numLogicalDims = 1;
        else
          numLogicalDims = numTopologicalDims;

        if (!meshMetaPtr) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Metadata not found for mesh '" << meshName
                              << "'. Returning NULL" << std::endl;
            return NULL;
        }

        // varDims.size() will always be one more than the logical
        // dims because it has an extra dim regardless if the vaiarble
        // is a component or not.

        // For a Structured Mesh the VarDims.size() will match the
        // numLogicalDims (numTopologicalDims) plus 1.

        // For an Unstructured Mesh the VarDims.size() is 2 regardless
        // if the values are nodal or zonal).

        if (varDims.size() != numLogicalDims + 1)
        {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "WARNING: The variable and the mesh do not "
                              << "have the same logical dimension. "
                              // << "Returning NULL."
                              << std::endl;
            // return NULL;
        }

        // For unstructured data, the variable can be subselected only when
        // the data is zonal. Also no parallel reads for unstructured data.
        if( meshMetaPtr->isUnstructuredMesh() )
        {
            haveDataSelections &= isZonal;
            parallelRead = false;
        }
    }

    bool isDouble = isDoubleType(varType);
    bool isFloat = isFloatType(varType);
    bool isInteger = isIntType(varType);

    if (!isDouble && !isFloat && !isInteger) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Error: hdf5 variable data type not handled: "
                          << varType << "Returning NULL." << std::endl;
        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "varDims[" << varDims.size() << "] = (";

    for (size_t i=0; i<varDims.size(); ++i)
      VsLog::debugLog() << " " << varDims[i];

    VsLog::debugLog() << ")" << std::endl;

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Variable " << name << " has dimensions =";

    for (size_t i=0; i<numLogicalDims; ++i)
      VsLog::debugLog() << " " << varDims[i+isCompMajor];

    VsLog::debugLog() << ", numLogicalDims = " << numLogicalDims
                      << ", isComponent = " << isAComponent << "." << std::endl;

    // Temporary array for variable counts as the selection is NODAL.
    std::vector<int> numVars(numLogicalDims);

    for (size_t i=0; i<numLogicalDims; ++i)
      numVars[i] = varDims[i+isCompMajor];

    // The variable dims should reflect the logical dims plus one
    // more dimension for the spatial dimension of the variable.
    size_t vsdim = numLogicalDims;
    std::vector<int> vdims(vsdim+1);

    // Adjust for the data selections which are NODAL. If no selection
    // the bounds are set to 0 and max with a stride of 1.
    GetSelectionBounds( numLogicalDims, numVars, vdims,
                        mins, maxs, strides, haveDataSelections, !isZonal );

#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)
    if (parallelRead)
    {
        if( !GetParallelDecomp( numLogicalDims, vdims, mins, maxs, strides,
                                !isZonal ) )
          return NULL; // No work for this processor.

        haveDataSelections = 1;
    }
#endif

    int numVariables = 1;
    for (size_t i=0; i<numLogicalDims; ++i)
      numVariables *= vdims[i];

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Total number of variables is " << numVariables
                      << std::endl;

    size_t varSize = H5Tget_size(varType); (void) varSize;

    // Read in the data
    void* dataPtr = 0;
    double* dblDataPtr = 0;
    float* fltDataPtr = 0;
    int* intDataPtr = 0;

    // Do the allocation here no matter the variable being read -
    // except for the case above.
    if (isDouble) {
        dblDataPtr = new double[numVariables];
        dataPtr = dblDataPtr;
    }
    else if (isFloat) {
        fltDataPtr = new float[numVariables];
        dataPtr = fltDataPtr;
    }
    else if (isInteger) {
        intDataPtr = new int[numVariables];
        dataPtr = intDataPtr;
    }

    if (!dataPtr) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Allocation failed, pointer is NULL.  "
                          << "Returning NULL." << std::endl;
        return NULL;
    }

    // Variable and mesh data or a variable component.
    if (vmMeta || isAComponent)
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Loading VarWithMesh data." << std::endl;

        herr_t err = reader->getData(variableDataset, dataPtr,
                                     indexOrder, componentIndex,
                                     mins, &(vdims[0]), strides);

        if (err < 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "GetVarWithMeshComponent returned error: "
                              << err << ".  Returning NULL." << std::endl;

            if (isDouble)
              delete [] dblDataPtr;
            else if (isFloat)
              delete [] fltDataPtr;
            else if (isInteger)
              delete [] intDataPtr;

            return NULL;
        }
    }

    // Read a regular variable
    else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Loading variable data." << std::endl;

        herr_t err;

        if( haveDataSelections )
          err = reader->getData( variableDataset, dataPtr,
                                 meta->getIndexOrder(), -2, // -2 no components
                                 mins, &(vdims[0]), strides );
        else
          err = reader->getData( variableDataset, dataPtr );

        if (err < 0) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "GetDataSet returned error: " << err
                              << ".  Returning NULL." << std::endl;

            if (isDouble)
              delete [] dblDataPtr;
            else if (isFloat)
              delete [] fltDataPtr;
            else if (isInteger)
              delete [] intDataPtr;

            return NULL;
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Finished reading the data, building VTK structures."
                      << std::endl;

    /* DEBUG

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Dumping data: " << std::endl;
    for (int i = 0; i < numVariables; i++) {
      if (H5Tequal(type, H5T_NATIVE_DOUBLE)) {
        VsLog::debugLog() << "data[" << i << "] = " << ((double*)data)[i]
                          << std::endl;}
      else if (H5Tequal(type, H5T_NATIVE_FLOAT)) {
        VsLog::debugLog() << "data[" << i << "] = " << ((float*)data)[i]
                          << std::endl;}
      else if (H5Tequal(type, H5T_NATIVE_INT)) {
        VsLog::debugLog() << "data[" << i << "] = " << ((int*)data)[i]
                          << std::endl;}
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Finished dumping data. " << std::endl;
    END DEBUG */

    vtkDataArray* rv = 0;

    if (isDouble) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Declaring vtkDoubleArray." << std::endl;
        rv = vtkDoubleArray::New();
    }
    else if (isFloat) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Declaring vtkFloatArray." << std::endl;
        rv = vtkFloatArray::New();
    }
    else if (isInteger) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Declaring vtkIntArray." << std::endl;
        rv = vtkIntArray::New();
    }

    //Attach offset information to array
    if (hasOffset) {
        vtkInformation* info = rv->GetInformation();
        info->Set(avtVariableCache::OFFSET_3(), offset[0], offset[1], offset[2]);
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Attaching nodeOffset information to dataset: "
                          << requestedName <<std::endl;
    }

    rv->SetNumberOfTuples(numVariables);

    // If in C order, perform permutation of index as VTK expect Fortran order

    // The index tuple is initially all zeros
    size_t* indices = new size_t[numLogicalDims];
    for (size_t k=0; k<numLogicalDims; ++k)
      indices[k] = 0;

    // Store data
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Storing " << numVariables << " data elements."
                      << std::endl;

    // Attempt to reverse data in place
    //#define IN_PLACE
#ifdef IN_PLACE
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Attempting to swap data in place." << std::endl;
    double* dblDataPtr = (double*) data;
    float* fltDataPtr = (float*) data;
    int* intDataPtr = (int*) data;

    // Step through by global C index and reverse
    if (numLogicalDims > 1) {
        for (size_t k = 0; k<numVariables; ++k) {
            // Accumulate the Fortran index
            size_t indx = indices[numLogicalDims-1];
            for (size_t j = 2; j<=numLogicalDims; ++j)
              indx = indx*dims[numLogicalDims-j] + indices[numLogicalDims-j];
            // Set the value in the VTK array at the Fortran index to the
            // value in the C array at the C index
            if (isDouble) {
                double tmp = dblDataPtr[indx];
                dblDataPtr[indx] = dblDataPtr[k];
                dblDataPtr[k] = tmp;
            }
            else if (isFloat) {
                float tmp = fltDataPtr[indx];
                fltDataPtr[indx] = fltDataPtr[k];
                fltDataPtr[k] = tmp;
            }
            else if (isInteger) {
                int tmp = intDataPtr[indx];
                intDataPtr[indx] = intDataPtr[k];
                intDataPtr[k] = tmp;
            } else {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Unknown data type: " << type << std::endl;
                return NULL;
            }
            // Update the index tuple
            size_t j = numLogicalDims;
            do {
                --j;
                ++indices[j];
                if (indices[j] == dims[j]) indices[j] = 0;
                else break;
            }while (j != 0);
        }
    }

    // Reversed in place so now can copy
    if (isDouble) {
        for (size_t k = 0; k<numVariables; ++k) {
            rv->SetTuple(k, &dblDataPtr[k]);
        }
    } else if (isFloat) {
        for (size_t k = 0; k<numVariables; ++k) {
            rv->SetTuple(k, &fltDataPtr[k]);
        }
    } else if (isInteger) {
        for (size_t k = 0; k<numVariables; ++k) {
            rv->SetTuple(k, &intDataPtr[k]);
        }
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Unknown data type: " << type << std::endl;
        return NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Done swapping data in place." << std::endl;
#else

    VsLog::debugLog() << CLASSFUNCLINE
    << "Swapping data into correct places, NOT using 'in place' code."
    << std::endl;

    // Using FORTRAN data ordering.
    if (isFortranOrder) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Using FORTRAN data ordering." << std::endl;

        if (isDouble) {
            for (size_t k = 0; k<(size_t)numVariables; ++k) {
                rv->SetTuple(k, &dblDataPtr[k]);
            }
        } else if (isFloat) {
            for (size_t k = 0; k<(size_t)numVariables; ++k) {
                rv->SetTuple(k, &fltDataPtr[k]);
            }
        } else if (isInteger) {
            for (size_t k = 0; k<(size_t)numVariables; ++k) {
                // Convert to float because SetTuple doesn't take ints
                float temp = intDataPtr[k];
                rv->SetTuple(k, &temp);
            }
        }
    } else {

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Using C data ordering." << std::endl;

        // Step through by global C index
        for (size_t k = 0; k<(size_t)numVariables; ++k) {

            // Accumulate the Fortran index
            size_t indx = indices[numLogicalDims-1];
            for (size_t j = 2; j<=numLogicalDims; ++j) {
                indx = indx*vdims[numLogicalDims-j] +
                indices[numLogicalDims-j];
            }

            // Set the value in the VTK array at the Fortran index to the
            // value in the C array at the C index
            if (isDouble) {
                rv->SetTuple(indx, &dblDataPtr[k]);
            }
            else if (isFloat) {
                rv->SetTuple(indx, &fltDataPtr[k]);
            }
            else if (isInteger) {
                // Convert to float because SetTuple doesn't take ints
                float temp = intDataPtr[k];
                rv->SetTuple(indx, &temp);
            }

            // Update the index tuple
            size_t j = numLogicalDims;
            do {
                --j;
                ++indices[j];
                if (indices[j] == (size_t)vdims[j])
                indices[j] = 0;
                else
                break;
            }while (j != 0);
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Done swapping data into correct places, "
                      << "NOT using 'in place' code." << std::endl;
#endif

    // Done with data
    delete [] indices;

    if (isDouble) {
        delete [] dblDataPtr;
    } else if (isFloat) {
        delete [] fltDataPtr;
    } else if (isInteger) {
        delete [] intDataPtr;
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return rv;
}

// *****************************************************************************
//  Method: avtVsFileFormat::getVariableMeta
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
VsVariable* avtVsFileFormat::getVariableMeta(int domain,
                                             std::string requestedName,
                                             int &componentIndex) {

    // Save the original name in a temporary variable
    // so that we can do some string manipulation on it
    std::string name = requestedName;

    componentIndex = -2;  // No components
    bool isAComponent = nameIsComponent(name, componentIndex);
    bool transform = isTransformedName(name); (void) transform;

    // The goal in all of the metadata loading is to fill one of
    // these two variables:
    VsVariable* meta = NULL;
    VsVariableWithMesh* vmMeta = NULL;
    VsDataset* variableDataset = NULL; (void) variableDataset;

    // It could be an MD variable if so, retrieve the md metadata,
    // look up the "real" variable name using the domain number, and
    // replace "name" with the name of that variable.
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Checking for possible MD var." << std::endl;

    VsMDVariable* mdMeta = registry->getMDVariable(name);
    if (mdMeta) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found MD metadata for this name: "
                          << name << std::endl;

        if (0 <= domain && (size_t)domain < mdMeta->getNumBlocks()) {
            meta = mdMeta->getBlock(domain);
            name = meta->getFullName();

            if( meta )
              variableDataset = registry->getDataset(meta->getFullName());

        } else {
            VsLog::warningLog()
              << CLASSFUNCLINE
              << "Requested domain number is out of bounds for this variable."
              << std::endl;
        }
    }

    // No meta data so, look for a "regular" variable with this name.
    if (meta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Looking for regular (non-md) variable." << std::endl;
        meta = registry->getVariable(name);

        if( meta )
          variableDataset = registry->getDataset(meta->getFullName());
    }

    // No meta data so, look for a VarWithMesh with this name.
    if (meta == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Looking for VarWithMesh variable." << std::endl;
        vmMeta = registry->getVariableWithMesh(name);

        if( vmMeta )
          variableDataset = registry->getDataset(vmMeta->getFullName());
    }

    // Haven't found metadata yet, so give up.
    if ((meta == NULL) && (vmMeta == NULL)) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "ERROR: Could not find metadata for name: "
                          << name << std::endl;
        return NULL;
    }

    return meta;
}

// *****************************************************************************
//  Method: avtVsFileFormat::NodalVar
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
vtkDataArray* avtVsFileFormat::NodalVar(VsVariable* meta,
                                        std::string name, int component)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    thisData.setReader(reader);
    thisData.setRegistry(registry);

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;

    return thisData.getData(meta, name, component);
}

// *****************************************************************************
//  Method: avtVsFileFormat::GetVar
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

vtkDataArray* avtVsFileFormat::GetVar(int domain, const char* requestedName)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    int component;
    VsVariable* meta = getVariableMeta(domain, requestedName, component);

    if( meta != NULL) {
        if(meta->getMesh()->isHighOrder()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Exiting nodal case." << std::endl;

            return NodalVar(meta, requestedName, component);
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Exiting standard case." << std::endl;

    return StandardVar(domain, requestedName);
}

// *****************************************************************************
//  Method: avtVsFileFormat::FreeUpResources
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::FreeUpResources(void)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    if (reader != NULL) {
        delete reader;
        reader = NULL;
    }

    if (registry) {
        delete registry;
        registry = NULL;
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterExpressions
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::RegisterExpressions(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    //get list of expressions from reader
    std::map<std::string, std::string>* expressions =
    registry->getAllExpressions();

    if (expressions->empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: No expressions found in file. Returning."
                          << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << expressions->size()
                          << " expressions in file." << std::endl;
    }

    //iterate over list of expressions, insert each one into database
    std::map<std::string, std::string>::const_iterator iv;
    for (iv = expressions->begin(); iv != expressions->end(); ++iv) {

        if (iv->first == "Rho") {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Ignoring expression " << iv->first << " = "
                              << iv->second << " because it crashesVisIt."
                              << std::endl;
            continue;
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Adding expression " << iv->first << " = "
                          << iv->second << std::endl;

        Expression e;
        e.SetName (iv->first);

        //TODO: if the user has supplied a label for a component but the
        // vsVar expression still refers to the old component name we
        // need to either 1. register the old component name as an extra
        // component or 2. edit the vsVar expression to replace old
        // component names with the user-specified labels.
        e.SetDefinition(iv->second);

        // What kind of variable should we register?
        // By default we use scalar
        e.SetType(Expression::ScalarMeshVar);

        if ((iv->second.size() > 0) && (iv->second[0] == '{')) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "It is a std::vector expression." << std::endl;

            e.SetType(Expression::VectorMeshVar);
        }
        else { // CURVE variable
               // Although this is not universally true, we make the
               // assumption that an expression defined on curve
               // variables will be a curve expression
            for (std::vector<std::string>::const_iterator it = curveNames.begin();
                    it != curveNames.end();
                    it++)
            {
                size_t foundIndex = std::string::npos;
                foundIndex = iv->second.find(*it);
                if (foundIndex != std::string::npos) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "It is a curve expression."
                                      << "Because an embedded curve name: "
                                      << *it << "  was found." << std::endl;

                    e.SetType(Expression::CurveMeshVar);

                    break;  // No need to stay in the loop
                }
            }
        }

        // If we've still got scalar, tell the user
        if (e.GetType() == Expression::ScalarMeshVar) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "It is a scalar expression." << std::endl;
        }

        //Add the new expression to the metadata object
        md->AddExpression(&e);
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterVars
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::RegisterVars(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Get var names
    std::vector<std::string> names;
    registry->getAllVariableNames(names);

    if (names.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: No variables were found in this file.  Returning." << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << names.size()
                          << " variables in this file." << std::endl;
    }

    std::vector<std::string>::const_iterator it;
    for (it = names.begin(); it != names.end(); ++it) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Processing var: "<< *it << std::endl;

        //get metadata for var
        VsVariable* vMeta = registry->getVariable(*it);

        //If this var is part of an MD var, we don't register it separately
        VsVariable* testForMD = registry->findSubordinateMDVar(*it);
        if (testForMD) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is part of an MD variable, "
                              << "will not be registered separately." << std::endl;
            continue;
        }

        // Name of the mesh of the var
        std::string meshName = vMeta->getMeshName();
        VsMesh* meshMeta = vMeta->getMesh();

        // Name of the transformed mesh (if it exists)
        //bool hasTransform = false;
        std::string transformMeshName = "";
        //VsRectilinearMesh* rectMesh = static_cast<VsRectilinearMesh*> (meshMeta);
        if (meshMeta && meshMeta->hasTransform()) {
            transformMeshName = meshMeta->getTransformedMeshName();
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Variable lives on a mesh with a transform: "
                              <<transformMeshName
                              << std::endl;
        }

        // Centering of the variable
        // Default is node centered data
        avtCentering centering = AVT_NODECENT;
        if (vMeta->isZonal()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is zonal." << std::endl;
            centering = AVT_ZONECENT;
        } else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is nodal." << std::endl;
        }

        // 1-D variable?
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Determining if var is 1-D." << std::endl;
        size_t numSpatialDims = 3;
        if (meshMeta) {
            numSpatialDims = meshMeta->getNumSpatialDims();
        } else {
            numSpatialDims = 3;
            VsLog::errorLog() << CLASSFUNCLINE
                              << "Unable to load mesh for variable?" << std::endl;
            VsLog::errorLog() << CLASSFUNCLINE
                              << "Using numSpatialDims = 3, hope it's right!"
                              << std::endl;
        }

        //if this mesh is 1-D, we leave it for later (curves)
        bool isOneDVar = false;
        if (numSpatialDims == 1) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is 1-D." << std::endl;
            isOneDVar = true;
        } else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is not 1-D." << std::endl;
            isOneDVar = false;
        }

        // Number of component of the var
        size_t numComps = vMeta->getNumComps();

        if (numComps == 0) continue;

        if (isOneDVar) {
            if (numComps > 1) {
                //go through list of components
                //generate a name for each one
                //then add to VisIt registry
                for (size_t i = 0; i < numComps; ++i) {
                    //First we look for a match in the component registry
                    //using var name and component index to search
                    std::string componentName = registry->getComponentName(*it, (int)i);

                    if (!componentName.empty()) {
                        VsLog::debugLog() << CLASSFUNCLINE
                                          << "Adding curve component "
                                          << componentName << "." << std::endl;
                        avtCurveMetaData* cmd =
                        new avtCurveMetaData(componentName.c_str());
                        curveNames.push_back(componentName);
                        cmd->hasDataExtents = false;
                        md->Add(cmd);
                    } else {
                        VsLog::debugLog() << CLASSFUNCLINE
                                          << "Unable to find match for curve variable in component registry."
                                          << std::endl;
                    }
                }
            } else {
                //When there is only one component, we don't create a component name
                //Instead, we just use the straight-up name
                VsLog::debugLog() << "Creating a curve." << std::endl;
                avtCurveMetaData* cmd = new avtCurveMetaData(*it);
                curveNames.push_back(*it);
                cmd->hasDataExtents = false;
                md->Add(cmd);
            }
        }
        else if (numComps > 1) {
            //go through list of components
            //generate a name for each one
            //then add to VisIt registry
            for (size_t i = 0; i < numComps; ++i) {
                //First we look for a match in the component registry
                //using var name and component index to search
                std::string componentName = registry->getComponentName(*it, (int)i);

                if (!componentName.empty()) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Adding variable component " << componentName << "." << std::endl;
                    avtScalarMetaData* smd = new avtScalarMetaData(componentName, meshName.c_str(), centering);
                    smd->hasUnits = false;
                    md->Add(smd);

                    if (vMeta->hasTransform()) {
                        std::string transformVarName = vMeta->getFullTransformedName();
                        std::string transformComponentName = registry->getComponentName(transformVarName, (int)i);
                        if (!transformComponentName.empty()) {
                            VsLog::debugLog() << CLASSFUNCLINE
                                              << "Registering transformed component: " <<transformVarName <<std::endl;
                            avtScalarMetaData* smd_transformed =
                            new avtScalarMetaData(transformComponentName.c_str(), transformMeshName.c_str(), centering);
                            smd_transformed->hasUnits = false;
                            md->Add(smd_transformed);
                        }
                    }

                } else {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Unable to find match for variable "
                                      << *it << "in component (" << i << ") registry." << std::endl;
                }
            }
        }
        else if (numComps == 1) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Adding single-component variable "
                              << *it << " attached to mesh "
                              << meshName << " with centering "
                              << centering << std::endl;
            avtScalarMetaData* smd =
            new avtScalarMetaData(*it, meshName.c_str(), centering);
            smd->hasUnits = false;
            md->Add(smd);

            if (vMeta->hasTransform()) {
                std::string transformVarName = vMeta->getFullTransformedName();
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Registering transformed variable: "
                                  << transformVarName <<std::endl;

                avtScalarMetaData* smd_transformed =
                  new avtScalarMetaData(transformVarName.c_str(),
                                        transformMeshName.c_str(), centering);

                smd_transformed->hasUnits = false;
                md->Add(smd_transformed);
            }

        }
        else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Variable '" << *it
                              << "' has no components. Not being added."
                              << std::endl;
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterMeshes
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::RegisterMeshes(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // All meshes names
    std::vector<std::string> names;
    registry->getAllMeshNames(names);

    if (names.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: no meshes were found in this file. Returning." << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << names.size() << " meshes." << std::endl;
    }

    std::vector<std::string>::const_iterator it;
    for (it = names.begin(); it != names.end(); ++it) {

        VsMesh* meta = registry->getMesh(*it);

        size_t numSpatialDims     = meta->getNumSpatialDims();
        size_t numTopologicalDims = meta->getNumTopologicalDims();

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Now registering mesh " << *it << " with "
                          << numSpatialDims << " spatial dimensions and "
                          << numTopologicalDims << " topological dimensions."
                          << std::endl;

        // If this mesh is a 1D curve leave it for later.
        if (numTopologicalDims == 1 && numSpatialDims == 1) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Found a topologically and spatially 1D mesh. "
                              << "Skipping for now, it will be added as a 1D curve mesh."
                              << std::endl;
            continue;
        } else if (((int)numSpatialDims <= 0) || (3 < numSpatialDims)) {
            VsLog::errorLog() << CLASSFUNCLINE
                              << "NumSpatialDims is out of range: "
                              << numSpatialDims << ".  "
                              << "Skipping mesh." << std::endl;
            continue;
        } else if (((int)numTopologicalDims < 0) || (3 < numTopologicalDims)) {
            VsLog::errorLog() << CLASSFUNCLINE
                              << "NumTopologicalDims is out of range: "
                              << numTopologicalDims << ".  "
                              << "Skipping mesh." << std::endl;
            continue;
        } else if (numSpatialDims < numTopologicalDims ) {
            VsLog::errorLog() << CLASSFUNCLINE
                              << "numTopologicalDims ("
                              << numTopologicalDims << ") is greater than the "
                              << "numSpatialDims ("
                              << numSpatialDims << ").  "
                              << "Skipping mesh." << std::endl;
            continue;
        }

        //If this mesh is part of an MD mesh, we don't register it separately
        VsMesh* testForMD = registry->findSubordinateMDMesh(*it);
        if (testForMD) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Mesh is part of an MD mesh, will not be registered separately."
                              << std::endl;
            continue;
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found mesh '" << *it << "' of kind '"
                          << meta->getKind() << "'." << std::endl;

        avtMeshType meshType = AVT_UNKNOWN_MESH;
        std::vector<int> dims;
        int bounds[3] = {1,1,1};
        size_t numCells = 1;

        //std::cout << "isDgMesh is " << meta->isDgMesh() << "\n";

        // Uniform Mesh
        if (meta->isUniformMesh()) {
            // 09.06.01 Marc Durant We used to report uniform cartesian
            // meshes as being 3d no matter what I have changed this to
            // use the correct mesh dimensions The changed plugin passes
            // vstests, and is motivated because the VisIt Lineout
            // operator requires 2-d data.  EXCEPT! then we can't plot 3-d
            // std::vectors on the 2-d data, so for now we continue to report 3
            // numSpatialDimss = dims.size();
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Mesh's dimension = " << numSpatialDims << std::endl;

            VsLog::debugLog() << CLASSFUNCLINE
                              << "Adding uniform mesh " << *it << "." << std::endl;

            meshType = AVT_RECTILINEAR_MESH;

            // Add in the logical bounds of the mesh.
            static_cast<VsUniformMesh*>(meta)->getNodeDims(dims);
            for( size_t i=0; i<dims.size(); ++i )
            {
                bounds[i] = dims[i]; // Logical bounds are node centric.
                numCells *= (dims[i]-1);
            }
        }

        // Rectilinear Mesh
        else if (meta->isRectilinearMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Adding rectilinear mesh" << *it << ".  "
                              << "numSpatialDims = " << numSpatialDims << "." << std::endl;

            VsRectilinearMesh* rectMesh = static_cast<VsRectilinearMesh*>(meta);
            meshType = AVT_RECTILINEAR_MESH;

            // Add in the logical bounds of the mesh.
            rectMesh->getNodeDims(dims);
            for( size_t i=0; i<dims.size(); ++i )
            {
                bounds[i] = dims[i]; // Logical bounds are node centric.
                numCells *= (dims[i]-1);
            }

            // Roopa: Check if there is a transformation specified for this
            // mesh. If so, register the transformed mesh here. The
            // original mesh will also be registered later by default
            if (rectMesh->hasTransform()) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Registering transform for rectilinear mesh"
                                  << *it << "." <<std::endl;
                std::string transformedMeshName = rectMesh->getTransformedMeshName();
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Adding rectilinear mesh" << *it << ".  "
                                  << "transformedMeshName = " << transformedMeshName
                                  << "." << std::endl;

                avtMeshMetaData* vmd =
                  new avtMeshMetaData(transformedMeshName, 1, 1, 1, 0,
                                      (int) numSpatialDims,
                                      (int) numTopologicalDims, meshType);

                vmd->SetBounds( bounds );
                vmd->SetNumberCells( (int)numCells );
                setAxisLabels(vmd, rectMesh->hasTransform());
                setGlobalExtents(vmd);
                md->Add(vmd);
            }
        }
        // Structured Mesh
        else if (meta->isStructuredMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Adding structured mesh "
                              << *it << "." << std::endl;

            meshType = AVT_CURVILINEAR_MESH;

            // Add in the logical bounds of the mesh.
            static_cast<VsStructuredMesh*>(meta)->getNodeDims(dims);
            for( size_t i=0; i<dims.size(); ++i )
            {
                bounds[i] = dims[i]; // Logical bounds are node centric.
                numCells *= (dims[i]-1);
            }
        }

        // Unstructured Mesh
        else if (meta->isUnstructuredMesh()) {

            VsUnstructuredMesh* unstructuredMesh = (VsUnstructuredMesh*)meta;

            // Unstructured meshes without connectivity data are registered
            // as point meshes
            if (unstructuredMesh->isPointMesh()) {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Registering mesh " << it->c_str()
                                  << " as AVT_POINT_MESH" << std::endl;

                meshType = AVT_POINT_MESH;
            }
            else {
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Registering mesh " << it->c_str()
                                  << " as AVT_UNSTRUCTURED_MESH" << std::endl;

                meshType = AVT_UNSTRUCTURED_MESH;
            }

            // Add in the logical bounds of the mesh.
            numCells = unstructuredMesh->getNumCells();

            bounds[0] = (int) numCells;
            bounds[1] = bounds[2] = 0;
        }

        /*
        else if (meta->isHighOrderUnstructuredMesh()) {
          VsHighOrderUnstructuredMesh* dgMesh = (VsHighOrderUnstructuredMesh*)meta;

         // Unstructured meshes without connectivity data are registered
         // as point meshes

         VsLog::debugLog() << CLASSFUNCLINE
                           << "Registering mesh " << it->c_str()
                           << " as AVT_UNSTRUCTURED_MESH" << std::endl;

         meshType = AVT_UNSTRUCTURED_MESH;

         // Add in the logical bounds of the mesh.  Number of cells
         // before each cell is triangulated
         numCells = dgMesh->getNumCells();

         bounds[0] = numCells;
         bounds[1] = bounds[2] = 0;
        }
        */
        else {

            meshType = AVT_UNKNOWN_MESH;

            VsLog::debugLog() << CLASSFUNCLINE
                              << "Unrecognized mesh kind: " << meta->getKind()
                              << "." << std::endl;

            continue;
        }

        if( meshType != AVT_UNKNOWN_MESH )
        {
            avtMeshMetaData* vmd =
              new avtMeshMetaData(it->c_str(), 1, 1, 1, 0,
                                  (int) numSpatialDims,
                                  (int) numTopologicalDims, meshType);

            vmd->SetBounds( bounds );
            vmd->SetNumberCells( (int) numCells );
            setAxisLabels(vmd);
            setGlobalExtents(vmd);
            md->Add(vmd);
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterMdVars
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::RegisterMdVars(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Get vars names
    std::vector<std::string> names;
    registry->getAllMDVariableNames(names);

    if (names.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: No MD variables were found in this file.  Returning."
                          << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << names.size()
                          << " MD variables in this file." << std::endl;
    }

    std::vector<std::string>::const_iterator it;
    for (it = names.begin(); it != names.end(); ++it) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Processing md var '"
                          << *it << "'." << std::endl;
        VsMDVariable* vMeta = registry->getMDVariable(*it);

        // Name of the mesh of the var
        std::string mesh = vMeta->getMesh();
        std::string vscentering = vMeta->getCentering();
        VsLog::debugLog() << CLASSFUNCLINE
                          << "MD var lives on mesh " << mesh << "." << std::endl;

        //TODO: Mesh should either exist in an mdMesh, or separately in
        //the list of meshes

        // Centering of the variable
        // Default is node centered data
        avtCentering centering = AVT_NODECENT;
        if (vMeta->isZonal()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is zonal" << std::endl;
            centering = AVT_ZONECENT;
        } else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Var is nodal" << std::endl;
        }

        // Number of component of the var
        size_t numComps = vMeta->getNumComps();

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Variable has " << numComps
                          << " components." << std::endl;

        if (numComps > 1) {
            for (size_t i = 0; i<numComps; ++i) {
                //first, get a unique name for this component
                std::string compName = registry->getComponentName(*it, (int)i);

                if (!compName.empty()) {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Adding variable component " << compName << "." << std::endl;
                    avtScalarMetaData* smd = new avtScalarMetaData(compName.c_str(),
                            mesh.c_str(), centering);
                    smd->hasUnits = false;
                    md->Add(smd);
                } else {
                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Unable to find component name for var "
                                      << *it << " and index " << i << std::endl;
                }
            }
        }
        else if (numComps == 1) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Adding single variable component " << *it
                              << "." << std::endl;
            avtScalarMetaData* smd =
            new avtScalarMetaData(*it, mesh.c_str(), centering);
            smd->hasUnits = false;
            md->Add(smd);
        } else {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Variable '" << *it
                              << "' has no components. Not being added."
                              << std::endl;
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterMdMeshes
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::RegisterMdMeshes(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    std::vector<std::string> names;
    registry->getAllMDMeshNames(names);
    if (names.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: no md meshes were found in this file. Returning" << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << names.size()
                          << " MD meshes in this file." << std::endl;
    }

    std::vector<std::string>::const_iterator it;
    for (it = names.begin(); it != names.end(); ++it) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << " Adding md mesh '"
                          << *it << "'." << std::endl;

        VsMDMesh* meta = registry->getMDMesh(*it);
        if (!meta) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Unable to find mesh " << *it << std::endl;
            continue;
        }

        avtMeshType meshType = AVT_RECTILINEAR_MESH; ///TODO: check fix for uninitialized value
        std::string kind = meta->getMeshKind();
        if (meta->isUniformMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Mesh is rectilinear" << std::endl;
            meshType = AVT_RECTILINEAR_MESH;
        } else if (meta->isUnstructuredMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Mesh is unstructured" << std::endl;
            meshType = AVT_UNSTRUCTURED_MESH;
        } else if (meta->isStructuredMesh()) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Mesh is structured" << std::endl;
            meshType = AVT_CURVILINEAR_MESH;
        }

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Mesh has dimension " << meta->getNumSpatialDims()
                          << "." << std::endl;

        avtMeshMetaData* vmd =
          new avtMeshMetaData(it->c_str(), (int)meta->getNumBlocks(), 1, 1, 0,
                              (int)meta->getNumSpatialDims(),
                              (int)meta->getNumSpatialDims(), meshType);
        setAxisLabels(vmd);
        setGlobalExtents(vmd);
        md->Add(vmd);
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::RegisterVarsWithMesh
//
//  Purpose:
//      Register both the mesh and the associated variables
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
void avtVsFileFormat::RegisterVarsWithMesh(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    std::vector<std::string> names;
    registry->getAllVariableWithMeshNames(names);

    if (names.empty()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "WARNING: no variables with mesh were found in this file. Returning."
                          << std::endl;
        return;
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Found " << names.size()
                          << " variables with mesh in this file." << std::endl;
    }

    std::vector<std::string>::const_iterator it;

    for (it = names.begin(); it != names.end(); ++it) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Processing varWithMesh '"
                          << *it << "'." << std::endl;

        VsVariableWithMesh* vMeta = registry->getVariableWithMesh(*it);

        // This loop registers all VARIABLES
        size_t numComps = vMeta->getNumComps();

        for (size_t i = 0; i < numComps; ++i) {

            //first, get a unique name for this component
            std::string compName = registry->getComponentName(*it, (int)i);

            if (!compName.empty()) {
                //register with VisIt
                VsLog::debugLog() << CLASSFUNCLINE
                                  << "Adding variable component "
                                  << compName << "." << std::endl;

                avtScalarMetaData* smd =
                  new avtScalarMetaData(compName.c_str(), it->c_str(),
                                        AVT_NODECENT);

                smd->hasUnits = false;
                md->Add(smd);

                // Register the transformed var (if this variable has
                // a transform)
                if (vMeta->hasTransform()) {
                    std::string transformMeshName =
                      vMeta->getTransformedMeshName();
                    std::string transformVarName =
                      vMeta->getFullTransformedName();
                    std::string transformComponentName =
                      registry->getComponentName(transformVarName, (int)i);

                    VsLog::debugLog() << CLASSFUNCLINE
                                      << "Registering a transformed component: "
                                      <<transformComponentName << std::endl;

                    avtScalarMetaData* smd_transformed =
                      new avtScalarMetaData(transformComponentName.c_str(),
                                            transformMeshName.c_str(),
                                            AVT_NODECENT);

                    smd_transformed->hasUnits = false;
                    md->Add(smd_transformed);
                }
            } else {
                VsLog::debugLog()
                  << CLASSFUNCLINE
                  << "Unable to get component name for variable "
                  << *it << " and index " << i << std::endl;
            }
        }

        // This loop registers all of the MESHES
        // Add in the logical bounds of the mesh.
        int numCells = (int)vMeta->getNumPoints();
        int bounds[3] = {numCells,0,0};
        int numSpatialDims     = (int)vMeta->getNumSpatialDims();
        int numTopologicalDims = (int)vMeta->getNumTopologicalDims();

        if (numSpatialDims == 1) {
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Found a 1D var with mesh, "
                              << "artificially elevating it to 2D."
                              << std::endl;
            numSpatialDims = 2;
        }

        VsLog::debugLog()
          << CLASSFUNCLINE
          << "Adding point mesh for this variable." << std::endl;

        avtMeshMetaData* vmd =
          new avtMeshMetaData(it->c_str(), 1, 1, 1, 0,
                              numSpatialDims, numTopologicalDims,
                              AVT_POINT_MESH);

        vmd->SetBounds(bounds);
        vmd->SetNumberCells(numCells);
        setAxisLabels(vmd);
        setGlobalExtents(vmd);
        md->Add(vmd);

        // Register the transformed mesh (if this variable has a transform)
        if (vMeta->hasTransform()) {
            std::string transformMeshName = vMeta->getTransformedMeshName();
            VsLog::debugLog() << CLASSFUNCLINE
                              << "Variable lives on a mesh with a transform: "
                              << transformMeshName << std::endl;

            avtMeshMetaData* vmd_transform =
              new avtMeshMetaData(transformMeshName.c_str(), 1, 1, 1, 0,
                                  numSpatialDims, numTopologicalDims,
                                  AVT_POINT_MESH);

            vmd_transform->SetBounds(bounds);

            // This is the change for ticket 3340: the transformed
            // vars with mesh use r,z, phi.
            // To revert, use false in the next call.
            setAxisLabels(vmd_transform, true);
            setGlobalExtents(vmd_transform);
            md->Add(vmd_transform);
        }
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::ActivateTimestep
//
//  Purpose:
//   Called to alert the database reader that VisIt is about to ask for data
//   at this timestep.  Since this reader is single-time, this is
//   only provided for reference and does nothing.
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::ActivateTimestep()
{
    LoadData();
}

// *****************************************************************************
//  Method: avtVsFileFormat::UpdateCyclesAndTimes
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//
/*
void avtVsFileFormat::UpdateCyclesAndTimes(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    if (!md) {
      VsLog::debugLog() << CLASSFUNCLINE
                        << "md was NULL, returning." <<std::endl;
        return;
    }

    int timeStep = 0;

    // Extract timestep from filename
    // First, get file name from full path
    std::string fileName(dataFileName);
    std::string::size_type lastSlash = fileName.find_last_of('/');
    if (lastSlash == std::string::npos) {
        lastSlash = fileName.find_last_of('\\');
    }
    VsLog::debugLog() << CLASSFUNCLINE
    <<"Last slash is " <<lastSlash << std::endl;
    if (lastSlash != std::string::npos) {
        std::string::size_type nameLength = fileName.length() - (lastSlash + 1);
        fileName = fileName.substr(lastSlash + 1, nameLength);
    }
    VsLog::debugLog() << CLASSFUNCLINE
                      <<"Extracted filename is \"" <<fileName <<"\"" << std::endl;

    // Timestep = the number between the last underscore and the first dot
    std::string::size_type lastUnderscore = fileName.find_last_of('_');
    VsLog::debugLog() << CLASSFUNCLINE
                      <<"lastUnderscore is " <<lastUnderscore << std::endl;

    std::string::size_type firstDot = fileName.find_first_of('.');
    VsLog::debugLog() << CLASSFUNCLINE
                      <<"firstDot is " <<firstDot << std::endl;

    if ((lastUnderscore != std::string::npos) &&
            (firstDot != std::string::npos) &&
            (firstDot > lastUnderscore + 1)) {
        std::string step =
        fileName.substr(lastUnderscore + 1, firstDot - (lastUnderscore + 1));

        VsLog::debugLog() << CLASSFUNCLINE
                          << "Step is \"" << step << "\""
                          << std::endl;

        timeStep = atoi(step.c_str());

        VsLog::debugLog() << CLASSFUNCLINE
                          <<"Converted to integer is \"" << timeStep << "\""
                          << std::endl;
    }

    // If time data is present, tell VisIt
    if (registry->hasTime()) {
        VsLog::debugLog() << CLASSFUNCLINE
        << "This file supplies time: "
        << registry->getTime() << std::endl;

        md->SetTime(timeStep, registry->getTime());
        md->SetTimeIsAccurate(true, registry->getTime());
    }

    // If time cycle is present, tell VisIt
    if (registry->hasCycle()) {
        VsLog::debugLog() << CLASSFUNCLINE
        << "This file supplies cycle: "
        << registry->getCycle() << std::endl;

        md->SetCycle(timeStep, registry->getCycle());
        md->SetCycleIsAccurate(true, registry->getCycle());
    }

    // If time data is present, tell VisIt
    // if (registry->hasTime()) {
    //     VsLog::debugLog() << CLASSFUNCLINE
    //                       << "This file supplies time: "
    //                       << registry->getTime() << std::endl;

    //     std::vector<double> times;
    //     times.resize( 1 );
    //     times[0] = registry->getTime();

    //     md->SetTimesAreAccurate(true);
    //     md->SetTimes( times );
    // }

    // If cycle data is present, tell VisIt
    // if (registry->hasCycle()) {
    //     VsLog::debugLog() << CLASSFUNCLINE
    //                       << "This file supplies cycle: "
    //                       << registry->getCycle() << std::endl;

    //     std::vector<int> cycles;
    //     cycles.resize( 1 );
    //     cycles[0] = registry->getCycle();

    //     md->SetCyclesAreAccurate(true);
    //     md->SetCycles( cycles );
    // }

    if (registry->hasLowerBounds() && registry->hasUpperBounds()) {

      VsLog::debugLog() << CLASSFUNCLINE
                        << "Getting bounds for mesh." << std::endl;

      std::vector<float> lowerBounds;
      registry->getLowerBounds(&lowerBounds);

      std::vector<float> upperBounds;
      registry->getUpperBounds(&upperBounds);
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}
*/

// *****************************************************************************
//  Method: avtVsFileFormat::LoadData
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::LoadData()
{
    if (reader)
      return;

    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    //Actually open the file & read metadata for the first time
    try {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Initializing VsReader()" << std::endl;

        if (!registry)
          registry = new VsRegistry();

        reader = new VsReader(dataFileName, registry);
    }
    catch (std::invalid_argument& ex) {
        std::ostringstream msg;
        msg << CLASSFUNCLINE
            << " Error initializing VsReader: " << ex.what();

        VsLog::debugLog() << msg.str() << std::endl;

        EXCEPTION1(InvalidDBTypeException, msg.str().c_str());
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::PopulateDatabaseMetaData
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::PopulateDatabaseMetaData(avtDatabaseMetaData* md)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    LoadData();

    // Tell visit that we can split meshes into subparts when running
    // in parallel

    // NOTE that we can't decompose domains if we have MD meshes
    // So it's one or the other

#ifdef VIZSCHEMA_DECOMPOSE_DOMAINS
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Decompose_domains is defined.  Entering code block."
                      << std::endl;
    if (registry->numMDMeshes() > 0) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "MD meshes are present in the data file.  "
                          << "Domain Decomposition is turned off." << std::endl;
        md->SetFormatCanDoDomainDecomposition(false);
    } else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "NO MD meshes are present in the data file.  "
                          << "Domain Decomposition is turned on." << std::endl;
        md->SetFormatCanDoDomainDecomposition(true);
    }
    VsLog::debugLog() << CLASSFUNCLINE
                      << "Decompose_domains is defined.  Exiting code block."
                      << std::endl;
#endif

    RegisterMeshes(md);
    RegisterMdMeshes(md);

    RegisterVarsWithMesh(md);

    RegisterVars(md);
    RegisterMdVars(md);

    RegisterExpressions(md);

    //add desperation last-ditch mesh if none exist in metadata
    if (md->GetNumMeshes() == 0 && md->GetNumCurves() == 0) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Warning: " << dataFileName
                          << " contains no mesh information. Creating default mesh."
                          << std::endl;
        avtMeshMetaData* mmd =
        new avtMeshMetaData("ERROR_READING_FILE", 1, 1, 1, 0, 3, 3,
                            AVT_RECTILINEAR_MESH);
        setAxisLabels(mmd);
        setGlobalExtents(mmd);
        md->Add(mmd);
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::setAxisLabels
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

void avtVsFileFormat::setAxisLabels(avtMeshMetaData* mmd, bool transform)
{
    VsLog::debugLog() << CLASSFUNCLINE << "entering." << std::endl;

    if (mmd == NULL) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Input pointer was NULL?" << std::endl;
        return;
    }

    VsMesh* mesh = registry->getMesh(mmd->name);
    VsVariableWithMesh* vwm = registry->getVariableWithMesh(mmd->name);
    if (mesh) {
       mmd->xLabel = mesh->getAxisLabel(0);
       mmd->yLabel = mesh->getAxisLabel(1);
       mmd->zLabel = mesh->getAxisLabel(2);
       VsLog::debugLog() << CLASSFUNCLINE
                         << "Exiting normally." << std::endl;
       return;
    }
    if (vwm) {
       mmd->xLabel = vwm->getAxisLabel(0);
       mmd->yLabel = vwm->getAxisLabel(1);
       mmd->zLabel = vwm->getAxisLabel(2);
       VsLog::debugLog() << CLASSFUNCLINE
                         << "Exiting normally." << std::endl;
       return;
    }
    // Both are zero, do default
    if (transform) {
       mmd->xLabel = "z";
       mmd->yLabel = "r";
       mmd->zLabel = "phi";
    } else {
       mmd->xLabel = "x";
       mmd->yLabel = "y";
       mmd->zLabel = "z";
    }

    VsLog::debugLog() << CLASSFUNCLINE << "exiting." << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::setGlobablExtents
//
//  Purpose:
//      How do you do the voododo that you do
//
//  Programmer: Allen Sanderson
//  Creation:   January, 2018
//
//  Modifications:
//
void avtVsFileFormat::setGlobalExtents(avtMeshMetaData* mmd)
{
  // If there are global bounds use them.
  if (registry->hasLowerBounds() && registry->hasUpperBounds()) {

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Getting bounds for mesh." << std::endl;

    std::vector<float> lowerBounds;
    registry->getLowerBounds(&lowerBounds);

    std::vector<float> upperBounds;
    registry->getUpperBounds(&upperBounds);

    double extents[6] = { lowerBounds[0], upperBounds[0],
                          lowerBounds[1],       upperBounds[1],
                          lowerBounds[2],       upperBounds[2] };

    mmd->SetExtents( extents );
  }
}

// *****************************************************************************
//  Method: avtVsFileFormat::GetCycle
//
//  Purpose:
//       This function gets called when VisIt tries "harder", otherwise "_i" in the file names is used.
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

int avtVsFileFormat::GetCycle() {
    VsLog::debugLog() << CLASSFUNCLINE << "entering" << std::endl;

    LoadData();

    if (registry->hasCycle()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "The file " << dataFileName << " has cycle: "
                          << registry->getCycle() << std::endl;
        return registry->getCycle();
    }
    else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "The file " << dataFileName << " has no cycle.  "
                          << "Returning INVALID_CYCLE." << std::endl;

        return INVALID_CYCLE;
    }
}


// *****************************************************************************
//  Method: avtVsFileFormat::GetTime
//
//  Purpose:
//        This function gets called when VisIt tries "harder".  Otherwise is not used."
//
//  Programmer: Marc Durant
//  Creation:   June, 2010
//
//  Modifications:
//

double avtVsFileFormat::GetTime() {
    VsLog::debugLog() << CLASSFUNCLINE << "entering" << std::endl;

    LoadData();

    if (registry->hasTime()) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "The file " << dataFileName << " has time: "
                          <<registry->getTime() << std::endl;

        return registry->getTime();
    }
    else {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "The file " << dataFileName << " has no time.  "
                          << "Returning INVALID_TIME." << std::endl;

        return INVALID_TIME;
    }
}

// *****************************************************************************
//  Method: avtVsFileFormat::GetSelectionBounds
//
//  Purpose:
//    The selction bounds does double duty for both structured and
//    unstructred mesh selections.
//
//    When the mesh is structured the numLogicalDims is the
//    numSpatialDims of the points and gdims.size() will be 3 because
//    mesh storage in VisIt are spatially 3D so the points must also
//    be 3D. The return values represent indexs in to the point
//    coordinates.
//
//    When the mesh is unstructured the numLogicalDims will be 1 as
//    will be gdims.size(). The return values represent indexs in to
//    the cells.
//
//  Programmer: Allen Sanderson
//  Creation:   July, 2011
//
//  Modifications:
//

void avtVsFileFormat::GetSelectionBounds( size_t numLogicalDims,
                                          std::vector<int> &numNodes,
                                          std::vector<int> &gdims,
                                          int *mins,
                                          int *maxs,
                                          int *strides,
                                          bool haveDataSelections,
                                          bool isNodal )
{
    // Adjust for the data selections which structured meshes are
    // NODAL or ZONAL based or for unstructured meshes are ZONAL based.
    if( haveDataSelections )
    {
        for (size_t i=0; i<numLogicalDims; ++i)
        {
            if( maxs[i] < 0 || numNodes[i] - 1 < maxs[i] )
            maxs[i] = numNodes[i] - 1; // last index, not size

            if( maxs[i] < mins[i] )
            mins[i] = 0;

            if( strides[i] > 1 )
            {
                int lastNode =
                  mins[i] + ((maxs[i] - mins[i]) / strides[i]) * strides[i];

                if( isNodal )
                {
                    // Make sure a complete stride can be taken
                    if( lastNode + strides[i] > maxs[i] )
                    maxs[i] = lastNode;
                }
                else // zonal
                {
                    // Make sure a complete stride can be taken
                    if( lastNode + strides[i] - 1 > maxs[i] - 1 )
                    maxs[i] = lastNode - 1;
                }
            }
        }
    }
    else
    {
        for (size_t i=0; i<numLogicalDims; ++i)
        {
            mins[i] = 0;
            maxs[i] = numNodes[i] - 1; // last index, not size
            strides[i] = 1;
        }
    }

    // The mins and maxs have three components so fill them in though
    // not used.
    for (size_t i=numLogicalDims; i<3; ++i)
    {
        mins[i] = 0;
        maxs[i] = 1;
        strides[i] = 1;
    }

    for (size_t i=0; i<numLogicalDims; ++i)
      gdims[i] = (maxs[i]-mins[i]) / strides[i] + 1; // Number of values

    // This gets executed for structured meshes when the
    // numLogicalDims (i.e. the numSpatialDims) is less than 3.
    for (size_t i=numLogicalDims; i<gdims.size(); ++i)
      gdims[i] = 1;

    if( haveDataSelections )
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Have a " << (isNodal ? "nodal" : "zonal")
                          << " inclusive selection  ";

        for (size_t i=0; i<(size_t)numLogicalDims; ++i)
        {
            VsLog::debugLog() << "(" << mins[i] << "," << maxs[i]
                              << " stride " << strides[i] << ") ";
        }

        VsLog::debugLog() << std::endl;
    }

    VsLog::debugLog() << CLASSFUNCLINE << "Dimensions ";

    for (size_t i=0; i<numLogicalDims; ++i)
      VsLog::debugLog() << gdims[i] << "  ";

    VsLog::debugLog() << std::endl;
}

// *****************************************************************************
//  Method: avtVsFileFormat::GetParallelDecomp
//
//  Purpose:
//    The selction bounds does double duty for both structured and
//    unstructred mesh selections.
//
//    When the mesh is structured the numLogicalDims is the
//    numSpatialDims of the points.
//
//    When the mesh is unstructured the numLogicalDims will be 1.
//
//  Programmer: Allen Sanderson
//  Creation:   July, 2011
//
//  Modifications:
//

bool avtVsFileFormat::GetParallelDecomp( int numLogicalDims,
                                         std::vector<int> &dims,
                                         int *mins,
                                         int *maxs,
                                         int *strides,
                                         bool isNodal )
{
#if (defined PARALLEL && defined VIZSCHEMA_DECOMPOSE_DOMAINS)

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Parallel & Decompose_Domains are defined, "
                      << "entering parallel code." << std::endl;

    // Get the axis with greatest number of nodes.
    int splitAxis = 0;

    for (size_t i=0; i<numLogicalDims; ++i)
    {
        if( dims[splitAxis] < dims[i] )
        splitAxis = i;
    }

    splitAxis = 0;

    // Integer number of nodes processor - note subtract off one node
    // because to join sections the "next" node is always added in. Thus
    // by default the last node will be added in.
    size_t numNodes = dims[splitAxis];
    size_t numNodesPerProc = (numNodes-1) / PAR_Size();
    size_t numProcsWithExtraNode = (numNodes-1) % PAR_Size();

    if( PAR_Rank() == 0 )
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "splitAxis = " << splitAxis << "  "
                          << "min = " << mins[splitAxis] << "  "
                          << "max = " << maxs[splitAxis] << "  "
                          << "strides = " << strides[splitAxis] << "  "
                          << "numNodes = " << numNodes << "  "
                          << "numNodesPerProc = " << numNodesPerProc << "  "
                          << "numProcsWithExtraNode = " << numProcsWithExtraNode
                          << std::endl;

        for( int i=0; i<PAR_Size(); ++i )
        {
            size_t min, max;

            // To get all of the nodes adjust the count by one for those
            // processors that need an extra node.
            if (i < numProcsWithExtraNode)
            {
                min = i * (numNodesPerProc + 1) * strides[splitAxis];
                max = min + (numNodesPerProc + 1) * strides[splitAxis] +
                // To get the complete mesh (i.e. the overlay between one
                // section to the next) add one more node. But for zonal and
                // point based meshes it is not necessary.
                (isNodal ? 0 : -1);
            }
            else
            {
                // Processors w/extra node plus processors without extra node.
                min = (numProcsWithExtraNode * (numNodesPerProc + 1) +
                        (i - numProcsWithExtraNode) * numNodesPerProc) *
                strides[splitAxis];

                max = min + (numNodesPerProc) * strides[splitAxis] +
                // To get the complete mesh (i.e. the overlay between one
                // section to the next) add one more node. But for zonal and
                // point based meshes it is not necessary.
                (isNodal ? 0 : -1);
            }

            // Number of nodes plus one if the node topology is greater than one.
            numNodes = (max-min) / strides[splitAxis] + 1;
            if( i == 0 || (i && numNodes > 1) )
              VsLog::debugLog() << CLASSFUNCLINE
                                << "Predicted bounds for processor " << i << "  "
                                << "min = " << min << "  max = " << max << "  "
                                << "strides = " << strides[splitAxis] << "  "
                                << "nodes = " << numNodes << std::endl;
            else
              VsLog::debugLog() << CLASSFUNCLINE
                                << "No work for processor " << i << std::endl;
        }
    }

    // To get all of the nodes adjust the count by one for those
    // processors that need an extra node.
    if (PAR_Rank() < numProcsWithExtraNode)
    {
        mins[splitAxis] = PAR_Rank() * (numNodesPerProc + 1) * strides[splitAxis];
        maxs[splitAxis] = mins[splitAxis] + (numNodesPerProc +1) * strides[splitAxis] +
        // To get the complete mesh (i.e. the overlay between one
        // section to the next) add one more node. But for zonal and
        // point based meshes it is not necessary.
        (isNodal ? 0 : -1);
    }
    else
    {
        // Processors w/extra node plus processors without extra node.
        mins[splitAxis] = (numProcsWithExtraNode * (numNodesPerProc + 1) +
                (PAR_Rank() - numProcsWithExtraNode) * numNodesPerProc) *
        strides[splitAxis];

        maxs[splitAxis] = mins[splitAxis] + (numNodesPerProc) * strides[splitAxis] +

        (isNodal ? 0 : -1);
    }

    // Number of nodes plus one if the node topology is greater than
    // one.  Point data meshes or for zonal variable data are the
    // cases where one does need to adjust for nodes.
    numNodes = (maxs[splitAxis]-mins[splitAxis]) / strides[splitAxis] + 1;

    dims[splitAxis] = numNodes;

    bool work;

    if( (PAR_Rank() == 0) || (PAR_Rank() && numNodes > 1) )
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Actual bounds for processor " << PAR_Rank() << "  "
                          << "min = " << mins[splitAxis] << "  "
                          << "max = " << maxs[splitAxis] << "  "
                          << "strides = " << strides[splitAxis] << "  "
                          << "nodes = " << numNodes << std::endl;
    }
    else
    {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "No work for processor " << PAR_Rank() << std::endl;
    }

    VsLog::debugLog() << CLASSFUNCLINE
                      << "Parallel & Decompose_Domains are defined, "
                      << "exiting parallel code." << std::endl;

    // If not on processor 0 and if the porcessor has only one node
    // skip it as it is slice which will have been drawn by the previous
    // processor.
    return( (PAR_Rank() == 0) || (PAR_Rank() && numNodes > 1) );

#endif
    return false;
}
#endif

// *****************************************************************************
//  Method: avtVsFileFormat::fillInMaskNodeArray
//
//  Purpose:
//      Fill in mask array (maskedNodes) from mask dataset
//
//  Programmer: Alex Pletzer
//  Creation:   October, 2011
//
//  Modifications:
//
template<typename TYPE>
void avtVsFileFormat::fillInMaskNodeArray(const std::vector<int>& gdims,
                                          VsDataset *mask,
                                          bool maskIsFortranOrder,
                                          vtkUnsignedCharArray *maskedNodes) {

    int numPoints = gdims[0] * gdims[1] * gdims[2];
    std::vector<TYPE> maskArray(numPoints);

    herr_t err = reader->getData(mask, &maskArray[0]);

    unsigned char* mp = maskedNodes->GetPointer(0);

    if (err < 0) {
        VsLog::debugLog() << CLASSFUNCLINE
                          << "Cannot read mask dataset " << std::endl;
    } else {
        if (maskIsFortranOrder) {
            for (size_t k = 0; k < (size_t)numPoints; ++k) {
                if (maskArray[k] != 0) {
                    avtGhostData::AddGhostNodeType(mp[k],
                                                   NODE_NOT_APPLICABLE_TO_PROBLEM);
                }
            }
        } else {
            // maskArray follows C index order, but
            // mp follows Fortran index order!
            for (int k = 0; k < numPoints; ++k) {
                int i0 = k % gdims[0];
                int i1 = (k / gdims[0]) % gdims[1];
                int i2 = (k / gdims[0] / gdims[1]) % gdims[2];
                int kC = i2 + gdims[2] * (i1 + gdims[1] * i0);
                if (maskArray[kC] != 0) {
                    avtGhostData::AddGhostNodeType(mp[k],
                                                   NODE_NOT_APPLICABLE_TO_PROBLEM);
                }
            }
        }
    }
}

// *****************************************************************************
//  Method: avtVsFileFormat::setStructuredMeshCoords
//
//  Purpose:
//     Set the node coordinates
//
//  Programmer: Alex Pletzer
//  Creation:   October, 2011
//
//  Modifications:
//
template<typename TYPE>
void avtVsFileFormat::setStructuredMeshCoords(const std::vector<int>& gdims,
                                              const TYPE* dataPtr,
                                              bool isFortranOrder,
                                              vtkPoints* vpoints) {

    int numPoints = gdims[0] * gdims[1] * gdims[2];
    int index[3];
    TYPE xyz[3];

    // mulSizes will be used to convert from a flat index to an index set.
    int mulSizes[3];
    if (isFortranOrder) {
        // Fortran order
        mulSizes[0] = 1;
        mulSizes[1] = gdims[0];
        mulSizes[2] = gdims[0] * gdims[1];
    } else {
        // C order
        mulSizes[0] = gdims[2] * gdims[1];
        mulSizes[1] = gdims[2];
        mulSizes[2] = 1;
    }

    for (int k = 0; k < numPoints; ++k) {

        // Set the base coordinates
        for (size_t j = 0; j < 3; ++j) {
            index[j] = (k / mulSizes[j]) % gdims[j];
            xyz[j] = dataPtr[3 * k + j];
        }

        // Set the node coordinates. Note: vpoints wants Fortran ordering,
        // regardless of whether isFortranOrder == true or not.
        int kF = index[0] + gdims[0] * (index[1] + gdims[1] * index[2]);

        vpoints->SetPoint(kF, xyz);
    }
}
